Classifications

• • B—PERFORMING OPERATIONS; TRANSPORTING
  • B42—BOOKBINDING; ALBUMS; FILES; SPECIAL PRINTED MATTER
  • B42D—BOOKS; BOOK COVERS; LOOSE LEAVES; PRINTED MATTER CHARACTERISED BY IDENTIFICATION OR SECURITY FEATURES; PRINTED MATTER OF SPECIAL FORMAT OR STYLE NOT OTHERWISE PROVIDED FOR; DEVICES FOR USE THEREWITH AND NOT OTHERWISE PROVIDED FOR; MOVABLE-STRIP WRITING OR READING APPARATUS
  • B42D25/00—Information-bearing cards or sheet-like structures characterised by identification or security features; Manufacture thereof
  • B42D25/30—Identification or security features, e.g. for preventing forgery
  • B42D25/324—Reliefs
• • B—PERFORMING OPERATIONS; TRANSPORTING
  • B42—BOOKBINDING; ALBUMS; FILES; SPECIAL PRINTED MATTER
  • B42D—BOOKS; BOOK COVERS; LOOSE LEAVES; PRINTED MATTER CHARACTERISED BY IDENTIFICATION OR SECURITY FEATURES; PRINTED MATTER OF SPECIAL FORMAT OR STYLE NOT OTHERWISE PROVIDED FOR; DEVICES FOR USE THEREWITH AND NOT OTHERWISE PROVIDED FOR; MOVABLE-STRIP WRITING OR READING APPARATUS
  • B42D25/00—Information-bearing cards or sheet-like structures characterised by identification or security features; Manufacture thereof
  • B42D25/20—Information-bearing cards or sheet-like structures characterised by identification or security features; Manufacture thereof characterised by a particular use or purpose
  • B42D25/21—Information-bearing cards or sheet-like structures characterised by identification or security features; Manufacture thereof characterised by a particular use or purpose for multiple purposes
• • B—PERFORMING OPERATIONS; TRANSPORTING
  • B42—BOOKBINDING; ALBUMS; FILES; SPECIAL PRINTED MATTER
  • B42D—BOOKS; BOOK COVERS; LOOSE LEAVES; PRINTED MATTER CHARACTERISED BY IDENTIFICATION OR SECURITY FEATURES; PRINTED MATTER OF SPECIAL FORMAT OR STYLE NOT OTHERWISE PROVIDED FOR; DEVICES FOR USE THEREWITH AND NOT OTHERWISE PROVIDED FOR; MOVABLE-STRIP WRITING OR READING APPARATUS
  • B42D25/00—Information-bearing cards or sheet-like structures characterised by identification or security features; Manufacture thereof
  • B42D25/30—Identification or security features, e.g. for preventing forgery
• • B—PERFORMING OPERATIONS; TRANSPORTING
  • B42—BOOKBINDING; ALBUMS; FILES; SPECIAL PRINTED MATTER
  • B42D—BOOKS; BOOK COVERS; LOOSE LEAVES; PRINTED MATTER CHARACTERISED BY IDENTIFICATION OR SECURITY FEATURES; PRINTED MATTER OF SPECIAL FORMAT OR STYLE NOT OTHERWISE PROVIDED FOR; DEVICES FOR USE THEREWITH AND NOT OTHERWISE PROVIDED FOR; MOVABLE-STRIP WRITING OR READING APPARATUS
  • B42D25/00—Information-bearing cards or sheet-like structures characterised by identification or security features; Manufacture thereof
  • B42D25/30—Identification or security features, e.g. for preventing forgery
  • B42D25/328—Diffraction gratings; Holograms
• • B—PERFORMING OPERATIONS; TRANSPORTING
  • B42—BOOKBINDING; ALBUMS; FILES; SPECIAL PRINTED MATTER
  • B42D—BOOKS; BOOK COVERS; LOOSE LEAVES; PRINTED MATTER CHARACTERISED BY IDENTIFICATION OR SECURITY FEATURES; PRINTED MATTER OF SPECIAL FORMAT OR STYLE NOT OTHERWISE PROVIDED FOR; DEVICES FOR USE THEREWITH AND NOT OTHERWISE PROVIDED FOR; MOVABLE-STRIP WRITING OR READING APPARATUS
  • B42D25/00—Information-bearing cards or sheet-like structures characterised by identification or security features; Manufacture thereof
  • B42D25/40—Manufacture
  • B42D25/405—Marking
  • B42D25/43—Marking by removal of material
  • B42D25/435—Marking by removal of material using electromagnetic radiation, e.g. laser

Definitions

• the invention relates to an optically variable security element and a manufacturing method for an optically variable security element.
• Optically variable security elements are well known in the art.
• DE 10 2013 021 806 A1 discloses a security element for displaying at least one optically variable information having a reflection layer which is formed from a grid of optically active elements which are formed by embossing elements of identical basic shape.
• the raster of optically active elements contains at least one optically variable information that can be detected in reflected illumination without aids in reflection.
• optically variable security element which, in addition to reflection images, contains a further security element. It is another object of the invention to provide a manufacturing method for an optically variable security element according to the invention. The object is achieved by an initially mentioned optically variable security element having the features of claim 1.
• the invention makes use of the idea of combing together two security features distributed over an optically effective surface of a variable security element.
• a relief layer is provided, which extends along the optically active surface of the security element.
• the relief layer has a plurality of identical individual optical elements.
• Each individual element has a single element surface subdivided into sub-surfaces having different directional reflectivities, and the sub-surfaces are grouped such that each group comprises a sub-surface of a single-element surface, and each group of sub-surfaces is an associated viewing-angle-dependent, visible to the naked eye reflection image coded.
• the plurality of individual optical elements forms a security feature based on the formation of reflection images.
• At least one planar region is provided in the relief layer, which extends between the individual optical elements and is provided with a diffraction grating structure applied over the at least one planar region, which generates viewing angle-dependent diffraction motifs visible to the naked eye through the predetermined directional illumination.
• the invention thus makes use of the idea to provide a diffraction grating structure between the reflective individual elements.
• the diffraction grating structure forms viewing angle-dependent diffraction motifs.
• the viewing angle-dependent diffraction motifs and the viewing angle-dependent reflection motifs form overall images which are likewise visible to the naked eye. Diffraction motifs and reflection motifs are interlaced with each other.
• first reflection motif is divided into first sub-motifs.
• the first partial motifs are assigned first directional reflectances, which encode the reflection motif. These are preferably either Partial surfaces with a high reflectance, preferably completely reflective, or areas with a very low reflectance, preferably completely absorbing.
• each sub-motif is assigned an equal degree of reflection over the entire extent of the sub-motif.
• the degree of reflection changes over the extent of one or more or all partial motifs.
• a relief layer is produced with a multiplicity of individual optical elements each having a single element surface.
• the individual optical elements may be arranged identically or differently or in two, three or any higher number of groups of similar elements in the relief layer.
• each of the single element surfaces is divided into disjoint sub-surfaces.
• each of the individual element surfaces is divided into identical and equally many sub-surfaces.
• Groups of sub-surfaces are formed, and the number of sub-surface groups suitably corresponds to the number of encoded reflection motifs.
• the number of reflection regions is greater than the number of coded motifs.
• a first group of sub-surfaces of various single-element surfaces is assigned to the first reflection motif, and the first group of sub-surfaces associated with the first reflection motif is provided with the first directional reflectances. That is, the first reflection motif, which is divided into first sub-motifs, is coded into a first group of sub-surfaces. It is preferably provided to use reflection motifs, which are formed of black color on a white background, and then form the black and white motif in partial motifs and each of the partial motifs either completely black or completely white. If one of the sub-motifs consists exclusively of white background, it is assigned a very low degree of reflection over its entire extent. If the sub-motif is formed exclusively black, the sub-motif is assigned a high degree of reflection over its entire extent.
• a sub-motif consists of areas of black color and white background, then the sub-motif is assigned different first directed reflectances.
• Essential to the invention is that the sub-surfaces are provided with directional reflectances, the reflection is thus non-diffusive.
• Reflectance is the ratio of the reflected to the incident light intensity.
• the directional reflectance referred to below is the ratio of the directionally reflected to the incident light intensity.
• the directional reflectance can also be called the degree of reflection.
• the optical variable security element according to the invention is based on different directional reflection. Therefore, it is particularly advantageous if the maximum directional reflectance of an optically variable security element according to the invention is particularly high, preferably at least in a visible wavelength range of more than 5%, preferably more than 10%, preferably more than 50% and optimally more than 90%. is.
• the illumination of the optically variable security element is preferably non-diffuse.
• diffuse illumination is referred to, which applies uniformly from all directions to the optically variable security element, for example, outdoor daylight in cloudy or extensive area light source or indirect light passing through a large illuminated area is generated.
• Non-diffuse lighting is referred to, which strikes the optically variable security element from a small and medium solid angle range, for example a point light source, a spotlight, a light bulb, a lamp, a neon tube, a window or sunlight.
• non-diffuse and diffuse light source is quite fluent and quite a non-diffused lighting can be realized by a cloudless sky in the sunshine and a diffuse lighting in a cloudy sky.
• the inventive optically variable behavior of the change occurs between the motifs also depends on the size of the reflection regions, which can be chosen to be smaller, the more non-diffuse the incident light is.
• the invention is based on the directed reflection of light on curved surfaces.
• a directionally-reflective curved surface When a directionally-reflective curved surface is illuminated by a non-diffuse light source, a viewer may recognize a reflection of the light source on the directionally-reflective curved surface at a location on the surface at which the surface normal to the surface is parallel to the bisector of the angle between a straight line of FIG the light source is the location on the surface and a line from the viewer to the location on the surface.
• angle of incidence equals angle of reflection
• angle of reflection can be fulfilled at several locations on a curved surface depending on the curvature, so that a viewer can perceive several specular reflections at different positions, places where this condition is not fulfilled or not
• the locations where reflective reflections are perceived are, for a curved surface, dependent on the position of the light source and the position of the viewer relative to the curved surface also the places on the surface, where a reflecting reflex is perceived, eg different mirroring reflexes can be perceived from different viewing positions.
• the curved surface and the differently directed reflecting sub-surfaces are coordinated so that a viewer perceives different reflection motifs from different viewing angles.
• These reflection motifs are composed of specular reflections.
• An advantage of the invention is that a specular reflection of light, depending on the reflectance, a high brightness and thus also the composite reflection motif. The greater the maximum directional reflectance of the surface, the brighter the reflection motif appears.
• the invention has significant advantages over the prior art.
• Conventional optically variable security elements in which the information layer is directly adjacent to the relief structure, are based on shading. As a result, the angle range needed to represent two different images separately must be very large. To completely separate two images by shading, they must be placed on surfaces at 90 ° to each other. If the angle is reduced, the shading is no longer complete. As a result, not many different motifs can be coded in an optically variable security element. In the case of quadrilateral pyramids, these are z. B. only four, in the case of corrugated metal structures only two.
• a shadowing proves surprisingly not necessary according to the invention.
• the observer sees from a certain viewing angle the specular reflections from which the reflection motif is assembled for this viewing angle.
• all or some other sub-surfaces can also be seen in this viewing angle (not shaded), ie. H. the groups of sub-surfaces of different reflectance intended for different viewing angles.
• a superimposition of several reflection motifs should actually be perceived.
• the disturbing reflection motifs are so dark in comparison to the specular reflections that they are only perceived as a homogeneous background. This perception as a homogeneous background is further enhanced by the small lateral size of the structures, which is preferably smaller than the resolving power of the human eye.
• positions of the first group of sub-surfaces on the single-element surfaces are determined by determining a position of visible reflection of a light source on each of the single-element surfaces from a given first viewing angle and the first group associated with a first reflection motif around the positions of the reflexes of the directed reflections is arranged on sub-surfaces.
• the first group of sub-surfaces, which is assigned to a first reflection motif is thus distributed on the individual element surfaces such that from a given viewing angle in a certain angles are formed on the optically variable security element first reflections of a preferably virtual point light source or a real non-diffuse light source and the first group of partial surfaces is formed around the first reflections, then the partial motifs of the first reflection motif are distributed.
• the optically variable security element according to the invention is preferably formed when at least one further motif is divided into further sub-motifs, each of which is assigned further directed reflectances, which respectively encode the further reflection motif, and the individual element surfaces are subdivided into further groups of sub-surfaces and further groups of sub-surfaces different individual element surfaces are each assigned to a further reflection motif and the at least one further reflection motif associated further groups are provided on sub-surfaces with the respective other directional reflection degrees.
• more than a single further motif namely also two, three or any even higher number of motifs, is to be understood as a further reflection motif.
• At least one further reflection motif is coded on the optically variable security element, wherein at least one further viewing angle deviating from the first viewing angle is chosen and at least one further position of at least one further directed reflection of the light source on each of the individual Element surfaces is determined and arranged around the at least one further position of the at least one further directed reflections around the at least one further reflection motif associated with another group of sub-surfaces.
• Multiple reflection motifs can be formed in a two-dimensional relief layer or a one-dimensional relief layer, as will be explained below.
• the invention works with arbitrary reliefs, ie curved surfaces containing areas of different directed reflectance. Even completely random freeform surfaces are possible.
• the calculation of which surface elements are covered by which reflectance is very complex and must be determined using 3D programs and simulations.
• the production of such elements also proves to be very complex.
• reliefs are preferred which, at least in some areas, have repetitive individual structures. Basically, one can with the repetitive individual structures distinguish between two-dimensional and essentially one-dimensional individual structures.
• each one of the M repeating individual elements is considered as a multiple motive point.
• the perceived brightness of a partial surface of the multiple motif points depends on the position and position of the light source, the security element and the observer as well as the directional reflectance at the point where the reflex appears.
• the M multiple motif points are each subdivided into N sub-surfaces, each of the N sub-surfaces of the M multiple-motif points corresponding to one of M sub-motives of one of N subjects.
• the directional reflectance of the N sub-surfaces of the M multiple-subject points is adjusted according to the brightness of the corresponding sub-motif of the subject.
• Has z. B the corresponding sub-motif a low brightness, a lower-reflectance is set and vice versa.
• Each of the N subjects can then be perceived by a viewer from a different viewing angle through specular reflexes.
• the two-dimensional structures are repeated in a regular two-dimensional grid.
• a grid may be orthogonal, hexagonal or otherwise regular.
• the individual elements can be concave, convex or convex / concave.
• the individual elements consist of hemispheres, spherical sections, semi-ellipsoids, ellipsoidal sections, parabolic sections or structures with slight deviations therefrom or otherwise arched individual elements.
• Substantially one-dimensionally, individual elements of the optically variable security element are designated whose length is significantly greater than their width and whose sectional image is essentially the same perpendicular to the long axis along this axis in the longitudinal direction.
• each of the K repeating individual elements is regarded as a motif line.
• This motive line is divided into M multiple motive points parallel to the one-dimensional structure.
• the perceived brightness of a partial surface of the multiple motif point depends on the position and location of the light source, the individual element and the observer as well as the directional reflectance at the point where the reflex appears.
• the light source should in this case have a minimum extension, the size of the optical variable security element corresponds.
• Each of the M sub-surfaces of the M multiple-subject points corresponds to one of M sub-motives of one of N subjects.
• the directional reflectance of the N reflection areas of the M multiple subject points is adjusted according to the brightness of the corresponding multiple subject point of the subject. Has z.
• the one-dimensional individual elements are repeated in a regular grid.
• the individual elements can be concave, convex or convex / concave.
• the sectional images of the individual elements consist of semicircles, circular sections, elliptical sections, parabolic sections or structures with slight deviations therefrom or otherwise arched structures.
• positions of the first group of sub-surfaces on the single-element surfaces are determined by determining from a given first observer position a position of a first reflection of visible directional reflection of a light source on each of the single-element surfaces, and surrounding the positions of the first reflections of the directed reflections first group associated with the first motif is arranged on sub-surfaces.
• a further observer position different from the first observer position is selected and a position of a further reflection of further directed reflection of the light source on each of the single element surfaces is determined Positions of the further reflections of the further directed reflection are arranged around the further motif associated further reflection areas.
• a non-diffused light emitting light source generates reflections on the individual element surfaces.
• the reflections are bright when the reflectance is high and low when the reflectance is low.
• the position of the reflections on the single element surface depends on the observer angle, with which the viewer looks at the optically variable security element at a predetermined position of the security element and a predetermined relative to the security element arrangement the light source. Depending on the viewing angle, the reflections travel along the individual element surfaces.
• the group of partial surfaces assigned to a reflection motif is fundamentally chosen such that further reflections associated with a further reflection motif can not be perceived from the first viewer position and, conversely, first reflections associated with the first reflection motif can not be perceived from a further viewer position can.
• the reflection regions and the further reflection regions reflect incident light in a directed manner.
• the profile layer is formed such that the first and the further reflection areas in non-diffuse light incidence from the other observer position or the first observer position are not visible and diffuse light incidence both the first and the further reflection motif both from the first and can be seen from the other observer position.
• the first and the further reflection areas are favorably arranged so that they do not shade each other, ie lie together in the viewing area of the viewer in preferably each of the observer positions. Reflections, however, are only recognizable to the viewer in directed reflection when it is in the first or in the further observer position.
• the relief layer according to the invention can have very low relief heights in order to achieve the desired alternating effect or tilting effect.
• the dimensions of the individual elements are on the order of magnitude below the resolution of the eye, which is 80 ⁇ m.
• An information layer is desirably applied to the relief layer by printing only the reflective areas of high reflectance with a metal-containing resist.
• the relief layer is first metallized completely and then the information layer formed by demetallizing reflection areas with low reflectance.
• the demetallization can preferably be carried out with a laser lithograph. Used laser lithographs are focused focused on the metallized layer. In practical embodiments, a diameter of the focused laser beam about 8 ⁇ , so that on individual elements with a diameter of about 40 ⁇ five different sub-motives can be applied.
• the relief layer is coated with a release lacquer in reflection regions with a low degree of reflection, the relief layer is then completely mirrored, and the release lacquer is subsequently washed out.
• the relief layer can be coated with an adhesion-promoting lacquer in the areas of reflection having a high degree of reflection, the relief layer then being completely mirrored, and the mirroring of the relief layer in the reflection areas being washed out without an adhesion-promoting lacquer.
• planar areas are provided between the individual elements. These planar regions may be contiguous or non-contiguous.
• the planar areas contain a diffraction grating structure.
• the diffraction grating structure may include diffraction gratings of a first group of diffraction gratings and diffraction gratings of plural groups of diffraction gratings.
• a group of diffraction gratings is defined by the same diffraction grating type, so that they have the same diffraction properties, ie in particular have the same lattice constant or the same lattice constants.
• the diffraction grating may be a line grid or a grid.
• each group of diffraction gratings may be characterized by having diffraction gratings of the same diffraction grating type.
• the diffraction gratings of a group can form a continuous or multiple diffraction grating.
• Each group of partial diffraction gratings encodes a diffraction motif. Both the diffraction motifs and the reflection motifs are visible to the naked eye.
• the optically variable security element is illuminated both with respect to the diffraction grating structure and with respect to the individual elements with the same directional illumination source and viewed from the same viewing angle with the naked eye.
• the geometry and the arrangement of the individual elements and the geometry and arrangement of the diffraction gratings are coordinated so that the viewing angle-dependent reflection motifs and the viewing angle-dependent diffraction motions generate viewing angle-dependent overall motifs that are visible to the naked eye.
• the reflection motifs and the diffraction motifs can be seen along the same optically active surface of the optically variable security element. They can be arranged directly next to each other, alternating and complementing each other.
• the concept of the overall motive is to be understood broadly here.
• these are to be understood as overall motifs which comprise at least one diffraction motif and at least one reflection motif in the same viewing angle.
• the diffraction and the reflection motif can be arranged side by side and thereby form each readable motifs;
• both the diffraction and the reflection motif each have a letter or a sequence of letters, a number or a sequence of numbers or mixtures of both o. ⁇ .
• the overall motif is a word, a security code, or the like, made up of the individual letters, letter sequences, numbers, or the sequences of numbers of both types of motifs.
• the single letter, the single number itself consists partly of a diffractive motive and partly of a reflection motif.
• the reflection motifs and diffraction motifs do not form any self-explanatory motifs.
• the overall motif becomes readable only when the two motifs interact simultaneously.
• the concept of the overall motif also includes a sequence or sequence of diffraction and reflection motifs. The result is obtained by changing the viewing angle, for example by tilting the optically variable security element. The temporal duration of tilting creates a temporal sequence of successive motifs.
• another subject either a diffractive or a reflection motif, will be visible, or one of the combinations of motifs described above will be visible at the same viewing angle.
• the viewer is presented as a total motive a sequence of motifs.
• a first viewing angle is a first subject to see in a second viewing angle, a second motif, etc. for the viewer.
• the first motif may be a reflection motif and the second motif may be a diffractive motif.
• An overall motif is therefore to be understood as meaning both a static overall motif which was described first and a dynamic overall motif in the form of a sequence, as described below.
• the diffraction grating structure is provided between the individual elements in planar areas. It is particularly advantageous that the planar and curved areas are provided alternately and are thus interlocked with each other.
• the diffraction grating structure contains groups of diffraction gratings with the diffraction properties which are the same in the groups but different from each other; these are the diffraction angles of the diffraction gratings and the individual diffraction angles. These are determined by the lattice constant of the diffraction gratings.
• the diffraction characteristics depend on the microstructure of a diffraction grating, which may be a rectangular structure, a sawtooth structure or a sinusoidal structure. They depend on whether they are phase or amplitude gratings or a mixed form of them. They depend on whether they are line grids or cross gratings.
• the diffraction gratings may also be blazed gratings which have substantially exactly one diffraction order.
• the lattice constant ie the repetition rate of the diffracting microstructures.
• the lattice constant essentially determines the angles at which diffraction orders occur.
• the planar areas contain groups of diffraction gratings of the same diffraction property.
• each of the group of diffraction gratings of the planar regions forms a diffraction motif that is visible in the diffraction angles and thus viewing angle dependent.
• the areas with diffraction gratings correspond to the motif, ie where the subject has bright areas, there are diffraction gratings of the associated group and where the image has dark areas, there are no diffraction gratings.
• the image has medium brightness, the image can be divided into light and dark areas by a halftoning process, as is known in the art of printing.
• An image composed of diffraction gratings will be called a diffraction image hereinafter.
• diffraction gratings cause a color splitting of white light, since the diffraction angle is dependent on the ratio of the wavelength of the light to the lattice constant.
• diffraction patterns appear when illuminated with white light in rainbow colors, they shimmer. The perceived color depends in particular on the illumination or viewing angle. If the viewing angle is increased in comparison to the surface normal, the diffraction pattern is first perceived in blue, then in green, then in orange / yellow and finally in red.
• the planar regions N include groups with diffraction gratings with N different diffraction properties.
• subareas of the planar regions having the same diffraction property assigned to the groups form a diffraction motif which is visible in the respective diffraction angles and thus viewing angle-dependent, resulting in the totality of N diffraction images.
• these N diffraction motifs are interlaced or superposed in the planar areas.
• at least one of the overall motifs arranged next to one another at a viewing angle has a complete reflection motif and a complete diffraction motif.
• a complete reflection motif for example a company logo, a number, a letter, a word, and a complete diffraction motif, likewise a company logo, a number, a letter, a word, can be recognized simultaneously in the viewing angle.
• the object is achieved in its other aspect by a manufacturing method of one of the above-described optically variable security elements.
• a master is produced with a negative of a relief layer having a multiplicity of identically constructed individual elements and with at least one planar region between the individual elements.
• the structure, the height profile of the relief layer, is formed negatively in the master. This can be z. B. done by lithographic techniques or by machining diamond machining.
• the relief layer is embossed by the master into a carrier substrate, for. B. by a hot stamping process or by a UV embossing process. It is preferably a rotary embossing process.
• the carrier substrate is coated with the embossed relief layer with a metal layer.
• the different reflectivities of sub-surfaces of single-element surfaces and partial regions with diffraction gratings are produced in a laser lithography method by processing the metal layer of the carrier substrate. Parts with low reflectance are demetallised.
• the partial regions are produced with diffraction gratings by demetallizing intermediate surfaces between grids of the diffraction grating.
• the diffraction grating has a grid or line structure with equal lattice constants in one direction. These are elevations or subsidence in the carrier layer.
• the grids themselves remain metallized so that they can diffract the incident light, but the interfaces between the grids are demetallised.
• the laser lithography process must be aligned exactly with the embossed structures to obtain the desired effects.
• Laser lithography is particularly advantageous when a series of security elements is produced in which each individual security element is individualized or serialized, ie, for example, carries its own serial number, which is optically variable.
• the master already contains diffraction gratings in the planar regions between the individual elements, which are also transferred into the material in the embossing process.
• the subregions are provided with diffraction gratings by covering, destroying or demetallizing the pre-embossed diffraction gratings at the locations where no diffraction grating is provided.
• an embossing cylinder is produced directly by diamond turning a raw cylinder.
• the structures are essentially one-dimensional.
• the geometry of the individual elements of the relief structure is in this case preferably predetermined by the diamond tool.
• the diffraction gratings in the planar areas can be made directly by turning a raw cylinder diamond by z.
• the grid lines are screwed directly with a diamond tool. In this case, the grid lines and the individual elements are arranged parallel to each other.
• the demetallization can preferably be carried out with a laser lithograph. Used laser lithographs are focused focused on the metallized layer. In practical embodiments, a diameter of the focused laser beam about 1 ⁇ to 20 ⁇ , so that up to forty different partial motifs can be applied to individual elements with a diameter of about 40 ⁇ .
• the relief layer according to the invention with its individual elements can have very low relief heights in order to achieve the desired alternating effect or tilting effect.
• the dimensions of the individual elements are on the order of magnitude below the resolution of the eye, which is about 80 ⁇ .
• Fig. 1 a is a schematic section of an optically variable according to the invention
• 1 b is a schematic view of a single element with adjacent planar portion
• FIG. 2 is nine illustrations showing the intermeshing of two reflection motifs with a diffraction motif in a two-dimensional grid of individual elements.
• FIG. 3 five illustrations showing the formation of two diffraction motives in two
• FIG. 4 shows ten diagrams illustrating the intermeshing of three reflection motifs and one diffraction motif in a one-dimensional grid of individual elements
• 5a shows an example of a motif sequence with two diffraction motifs arranged outside the reflection motifs
• 5b shows an example of a motif sequence with two diffraction motifs arranged within the reflection motifs
• 5c shows an example of a motif sequence with a diffraction motif arranged within the reflection motifs
• FIG. 7 shows three examples of a combination of diffraction and reflection motifs
• 8 shows an example of a motif sequence with diffraction motifs visible in different colors and reflection motifs visible in the same viewing angles
• FIG. 9 shows a further example of a motif sequence with diffraction motifs visible in different colors and reflection motifs visible at the same viewing angles
• FIG. 7 shows three examples of a combination of diffraction and reflection motifs
• 8 shows an example of a motif sequence with diffraction motifs visible in different colors and reflection motifs visible in the same viewing angles
• FIG. 9 shows a further example of a motif sequence with diffraction motifs visible in different colors and reflection motifs visible at the same viewing angles
• Fig. 1 refractive behavior of a beam path of a diffraction and a
• 1 a schematically shows a sectional view of an optically variable security element 1 according to the invention.
• 1 a shows a relief structure with four periodically repeating individual elements 2 with planar areas 3 arranged therebetween.
• Fig. 1 b one of the individual elements 2 and an adjacent planar region 3 are shown schematically as well as both the individual element 2 and on the planar region 3 incident directed light 4.
• the light 4 in a large angular range Reflection on a single element surface 6 is reflected on a surface normal at a reflection point according to the reflection law "angle of incidence equals angle of reflection.”
• angle of incidence equals angle of reflection.
• the single-element surface 6 is partially mirrored, with a high degree of reflection at the partial surfaces in which a lot of light is reflected g light is reflected, a low reflectance, so no mirroring is provided.
• planar areas 3 there are partial areas with diffraction gratings, which bend the light 4 into a diffraction order or several diffraction orders.
• 2 shows the construction of the optically variable security element 1 with two reflection motifs, the letters F and T, and a diffraction motif, the letter L.
• the two reflection motifs and the one diffraction motif are shown in the first line of FIG.
• the two reflection motifs F, T are coded in the different reflectance of the sub-surfaces of the individual elements 2 which repeat periodically in the X and Y directions.
• the individual elements 2 are here dome-shaped bulges or dome-shaped indentations.
• the repeating individual elements 2 according to the invention are shown in the second row of FIG. 2 at the far left. Between the individual elements 2, the planar areas 3 are provided. This is the contiguous area between the individual elements 2 which are circular in cross-section parallel to the plane of the optically variable security element 1.
• the second image of the second row shows how the individual surfaces 6 are divided into sub-surfaces 61, 62 with different degrees of reflection.
• the sub-surfaces are divided into a first group of sub-surfaces 61 that encode the letter F and a second group of sub-surfaces 62 that encode the letter T.
• Each single element surface 6 is disjointly divided into the sub-surfaces 61, 62 of the first and second groups.
• Black indicates a high reflectance and white a very low reflectance, d. H.
• the sub-surfaces 61, 62 of the individual element surfaces 6, which are marked in black, are fully mirrored, while the sub-surfaces 61, 62 of the individual elements 1, which are marked white, are antireflected. This gives the impression that when looking at the plurality of individual elements 2 arranged in a grid at a first viewing angle of the letter F and at a second viewing angle, the letter T appears as a reflection motif.
• a diffraction grating is now additionally provided in the partial region 31 of the planar region 3 which extends in an L-shaped manner according to the third illustration of the second line of FIG. 2, which diffraction grating is defined by a specific diffraction grating type.
• the letter L can therefore be seen in the same directional illumination by the light 4 in a diffraction angle determined by the diffraction grating type.
• the third line of Fig. 2 shows how the letters F and T composed by individual reflections on the associated sub-surfaces 61, 62 each to a reflection motif are and the letter L, which is formed here by the contiguous portion 31 of the planar portion 3. If the size of the individual elements 2 is below the resolution of the human eye, ie, below about 50 ⁇ , the viewer is given the impression of continuous illuminated lines, and he no longer registers the individual reflections or the holes in the diffraction motif.
• FIG. 2 represent the basic principle of creating an optically variable security element 1 according to the invention.
• the ratios would be chosen differently.
• So z. B. a figure to be displayed 5 mm in size, while the individual elements z. B. in a grid of 50 ⁇ would repeat.
• the figure is composed of 100 ⁇ 100 individual elements 2 whose size, in turn, lies below the resolution limit of the eye.
• the human observer can not perceive the individual pixels separately from one another, which results in continuous individual images for him-both in the case of the reflection motifs F, T and in the diffraction motifs L.
• FIG. 3 shows an enlargement of the illustration in FIG. 2.
• a second diffraction motif is integrated into the optically variable security element 1. It is the letter H, which is integrated in addition to the letter L as the second diffraction motif.
• the planar region 3 is subdivided into two groups of partial regions 31, 32, as the second illustration of FIG. 3 shows.
• the first group of partial regions 31, unlike the partial region of FIG. 2, is no longer contiguous, but the first group of partial regions 31 which codes the letter L consists of five individual first diffraction grating types, such as the left-hand representation of the second row in FIG 3 shows that together with directed light incidence, the letter L is generated in a diffractive motif, while the letter H is coded in a second group of sub-regions 32 coded in nine individual second diffraction grating types, like the second representation of the second row in FIG. 3 shows.
• FIG. 4 shows the construction of the optically variable security element 1 when the individual elements 2 are groove-shaped or semi-cylindrical or rib-shaped.
• the individual element 2 may extend over an entire length L of the optically variable security element 1, while the individual element 2 is repeated along a width B at periodic intervals.
• 4 shows the basic design of the individual elements 2.
• Each of the individual elements 2 is subdivided along its longitudinal direction into three rows of five pixels each. The pixels all have an equal length extension and an equal but narrower extent along the width B of the individual element 2.
• Each of the individual elements 2 is divided into five pixels along the length L and three pixels along the width B.
• FIG. 4 shows the coding of the three reflection motifs F, T and N by a corresponding choice of the reflectivities of the first, second or third row of pixels and the one diffractive motif L.
• the diffraction motif L is placed in the planar region 3 between the elongate individual elements 2 in FIG a first group of partial regions 31 is coded with a diffraction grating, while the three reflection motifs are each coded in a group of partial surfaces, wherein the first group of partial surfaces comprises the uppermost row of the pixels, the second group of partial surfaces the middle pixels and the third group Sub-surfaces comprises the lower pixels of the single element surfaces 6.
• the dark mark again shows to what extent the individual element surfaces 6 are mirrored along their longitudinal direction.
• FIGS. 5a, 5b and 5c each show an example of a possible motif sequence.
• the scale indicates the viewing angle.
• the viewing angle ⁇ is given in this example when the viewer is in the direction of the zeroth order of the diffraction grating.
• the reflection motifs are formed as an image sequence 1 -2-3-4-5 which is visible in a certain viewing angle range, and the diffraction image B is visible at a viewing angle outside the viewing angle range of the reflection motif sequence.
• the diffraction motif B is visible under at least two viewing angles, the are arranged symmetrically around the viewing angle 0 around. It should be noted that this symmetry is not present in the reflection motif sequence.
• the numbers 1 -2-3-4-5 and the letter B stand for any content of the motifs. The contents may be logos, texts, serial numbers, symbols, photos, etc.
• the image sequence 1 -2-3-4-5 may be an animation, e.g. B. a motion or zoom animation.
• other diffraction motifs may also be present.
• the first image information is an image sequence 1 -2-3-4-5, which is visible in a certain viewing angle range except for two viewing angles, and the diffraction image B is visible in the two recessed viewing angles.
• Fig. 5c is shown the reflection motif sequence 1 -2-3-4-5-6 which is visible in a certain viewing angle range except for one viewing angle, and the diffraction image B is visible at the recessed viewing angle. Since this example is an asymmetric, blazed diffraction grating, the diffraction image B is visible under exactly one viewing angle.
• the reflection motifs are visible as image sequence 1 -2-3-4-5- 6-7 in a certain viewing angle range, and the diffraction image B is visible in two symmetrical diffraction angles.
• the respectively visible image of the image sequence (image 3 and image 5) and the visible diffraction image B are matched to one another in the diffraction angles.
• the respective motifs may be the same in parts or disjoint in parts, or in parts or complementary content.
• FIG. 7 shows two contents in the left-hand representation: a customer logo "BRAND TM " as a reflection motif and a serial number "9 8 1 3 0" as a diffraction motif.
• the customer logo appears as a silvery font, while the serial number shimmers in rainbow colors.
• Both motifs appear essentially in the same area of the optically variable security element 1 and at the same viewing angle.
• the reflection motif is represented as filled in the representation and the diffraction motif as an outline. In the middle representation, only one content is considered Overall theme shown, with the content of the reflection motif and the diffraction motif is divided.
• the first three digits 9 8 1 of the serial number are shown as a reflection motif and the last two digits 3 0 of the serial number as a diffraction motif.
• a content is represented as a total motif, the content being divided between the reflection and the diffraction motifs.
• the upper half of the serial number 9 8 1 3 0 is the reflection motif, while the lower half represents the diffraction motif.
• the reflection motifs are shown as a motif sequence 1, 2, 3, 4, 5, 6, 7, each visible in a certain viewing angle range, and the diffraction motifs are shown here as letter B.
• the letter B is visible in a diffraction angle range. Since the individual colors differs at the same diffraction grating type differently when the light incidence of white light, the diffraction angle of the different colors can be adapted to the viewing angle of the different reflection motifs, so that the appearance of the reflection motif "3" letter B in blue, when the reflection motif "4" the letter B in green and the appearance of the reflection motif "5" the letter B in red perceived.
• Fig. 9 shows a similar example.
• the diffraction motif here serial number 98130
• the diffraction motif here serial number 98130
• the content of the reflection image matched thereto that is to say in FIG. 8 of the third image, of the image sequence is visible.
• the text "blue” In a viewing angle in which the diffraction information gives a green color impression, the content of the fourth image matched thereto is visible in a text "green” according to FIG.
• the diffraction information gives a red color impression
• the content of the fifth image matched to FIG. 8 of the image sequence is visible in a text "red”.
• Fig. 10 shows an example of a layer structure of the invention.
• a substantially transparent carrier layer 100 made of polymer.
• the relief structure which is embossed in a substantially transparent lacquer layer 101 adjacent to the carrier layer 100.
• a metallized layer 102 in which the sub-surfaces with different reflectance and the sub-areas with diffraction gratings are located.
• a contrasting layer 103 which simultaneously acts as an adhesive layer. All layers 100, 101, 102, 103 Extend over the entire areal extent of the optically variable security element. 1
• FIG. 11 shows different beam paths over the metallized layer 102 over a planar region 3 and a single element 2 when a medium with a refractive index n is located above the metallized layer 102.
• the wavelength ⁇ in the lacquer layer 101 with refractive index n is shortened by the factor 1 / n with respect to the wavelength in air.
• the sine of the diffraction angle in the medium is also smaller by a factor of 1 / n.
• the refractive index n of the layer 101 lying above the relief structure is taken into account by compensating for the angular magnification of the reflection motifs caused by the refractive index n in the design of the optically variable security element 1. Compensation can be done either by an adapted selection of the geometry of the individual elements 1, wherein in general the curvatures of the geometry are reduced with a larger refractive index or the same geometry by changing or shifting the areas of different reflection.

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• 2016
  • 2016-08-04 DE DE102016214407.3A patent/DE102016214407A1/de not_active Ceased
• 2017
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