EP2595817B1 - Optically variable security element with tilt image - Google Patents

Description

The invention relates to an optically variable security element for securing data carriers with a tilting image of first and second identifications which can be recognized from different first and second viewing directions. The invention also relates to a method for producing such a security element and to a data carrier equipped with such a security element.

Data carriers such as identification cards, credit cards, bank cards and the like are increasingly being used in various service sectors, but also in the in-house area. They usually have to meet two opposing conditions. Because of their widespread use, they are a mass-produced product that should be simple and inexpensive to produce. On the other hand, they should offer the greatest possible security against counterfeiting or falsification due to their legitimacy function. A visually appealing appearance of the security features used also contributes to a high level of protection against counterfeiting, as attractive security features are more closely respected by the user and easier to memorize. The variety of available types of cards, particularly magnetic stripe cards and smart cards, is testimony to the numerous efforts and various suggestions as to how these conflicting requirements can be properly combined.

In this context, it is known to provide data carriers 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, 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 parallel to the axis of the cylindrical lenses.

Based on this, the invention has for its object to provide a security element of the type mentioned, which is simple and inexpensive to manufacture and combines an attractive visual appearance with high security against counterfeiting.

This object is achieved by the security element having the features of the main claim. A method for producing such a security element and a data carrier with such a security element are specified in the independent claims. Further developments of the invention are the subject of the dependent claims.

According to the invention, in a generic security element, the first and second markings of the tilt image are present in an optically variable recording layer having a reflection layer formed by a vacuum vapor method. The security element further includes a viewing element grid spaced from the recording layer, which displays the first and second indicia, respectively, as viewed from the first and second viewing directions.

The combination of a viewing element grid with an optically variable recording layer produces an optically multivariable security element in which the first optically variable effect of the tilt image and the second optically variable effect of the recording layer interact with one another and visually enhance each other. By the further Characteristic that the recording layer comprises a reflection layer generated by a vacuum vapor method, a simple and inexpensive introduction of a desired tilting image is possible in the security element. The use of costly optically variable inks can thus be dispensed with. Although the use of relatively expensive laser technology for generating the markings is expedient, it is not absolutely necessary for the production of security elements according to the invention. Rather, the markings can also be introduced into the recording layer by a large-area mask exposure or by other demetallization methods, such as washing, etching or oil ablation.

The proposed security element thus combines a high degree of protection against counterfeiting with an attractive visual appearance and a simple and cost-effective production.

The optically variable recording layer preferably contains a thin-film element with a color-shift effect. In this case, the thin-film element advantageously has a reflection layer, an absorber layer and a dielectric spacer layer arranged between the reflection layer and the absorber layer. The first and / or second markings in this case are preferably formed by recesses in the absorber layer and / or the reflection layer and / or in the dielectric spacer layer.

In one development of the invention, the first and / or second markings respectively comprise first and second part markings, wherein the first part markings are formed by recesses only in the absorber layer and the second part markings are formed by cutouts are formed both in the absorber layer and in the reflection layer, so that the security element shows different tilting images in plan view and see through.

The first and second markings may be introduced into the optically variable recording layer from different directions through the viewing element grid in all designs with laser radiation. If the markings respectively comprise the abovementioned first and second part markings, then they are advantageously introduced into the optically variable recording layer with laser radiation having different laser energy through the viewing element grid.

In an advantageous variant of the invention, the reflection layer of the optically variable recording layer is present over the entire area at least outside the markings.

In another, likewise advantageous variant of the invention, the reflection layer of the optically variable recording layer outside the markings is rastered at least in partial regions and consists in these subregions of a multiplicity of raster elements which are formed by recesses in a substantially opaque layer, or by a substantially opaque, spaced pattern primitive are formed. The screened subregions of the reflection layer advantageously form a motif in the form of patterns, characters or an encoding that becomes visible when the security element is viewed through.

The raster elements of the reflection layer can be arranged regularly or stochastically. A stochastic arrangement may in particular be used to avoid unwanted moiré effects. In a Advantageous embodiment, the grid elements are circular, preferably with a diameter between 10 .mu.m and 100 .mu.m, or linear, preferably formed with a width of 30 microns to 70 microns.

The viewing element grid is advantageously formed from a plurality of microlenses, in particular of cylindrical lenses or spherical lenses, or of a plurality of micromill mirrors.

The reflection layer is preferably made of a metal, in particular of aluminum. However, other metals, such as silver, nickel, copper, iron, chromium, gold, alloys of these or other metals or other highly reflective materials come into consideration. Preferably, the optically variable recording layer is separated from the viewing element grid by a transparent spacer layer.

• eine optisch variable Aufzeichnungsschicht mit einer im Vakuumdampfverfahren erzeugten Reflexionsschicht hergestellt wird,
• in die optisch variable Aufzeichnungsschicht erste und zweite Kennzeichnungen eingebracht werden, und
• die optisch variable Aufzeichnungsschicht im Abstand mit einem Betrachtungselementraster kombiniert wird, das bei Betrachtung aus unterschiedlichen ersten bzw. zweiten Betrachtungsrichtungen die ersten bzw. zweiten Kennzeichnungen zeigt, so dass die ersten und zweiten Kennzeichnungen ein Kippbild bilden.

The invention also includes a method for producing an optically variable security element for securing data carriers in the

• an optically variable recording layer is produced with a reflection layer produced in the vacuum vapor method,
• in the optically variable recording layer first and second markings are introduced, and
• the optically variable recording layer is spaced apart with a viewing element grid which, when viewed from different first and second viewing directions, respectively, shows the first and second marks, respectively, such that the first and second marks form a tilt image.

In an advantageous variant of the method, the first and second markings are introduced with laser radiation from different directions through the viewing element grid into the optically variable recording layer.

In another, likewise advantageous variant of the method, the first and second markings are introduced into the optically variable recording layer by a washing, etching or oil ablation method.

The invention also includes a data carrier, in particular a brand article, a document of value, an identity card and the like, with a security element of the type described. The invention offers particular advantages with data carriers in the form of cards, such as credit cards, bank cards, cash cards, authorization cards, identity cards or passport personalization pages ,

Fig. 1

eine Aufsicht auf eine Identifikationskarte mit einem erfindungsgemäßen Sicherheitselement,

Fig. 2

schematisch einen Querschnitt der Karte der Fig. 1 entlang der Linie II-II,

Fig. 3

in (a) bis (c) drei Ausführungsbeispiele der Erfindung, bei denen die optisch variable Aufzeichnungsschicht jeweils durch ein Dünnschichtelement mit Farbkippeffekt gebildet ist,

Fig. 4

ein Sicherheitselement mit einer gerasterten Reflexionsschicht nach einem Ausführungsbeispiel der Erfindung,

Fig. 5

ein Sicherheitselement mit einer teilweise vollflächig und teilweise gerastert vorliegenden Reflexionsschicht nach einem anderen Ausführungsbeispiel der Erfindung, und

Fig. 6

ein Sicherheitselement mit einem Betrachtungselementraster aus einer Mehrzahl von Mikrohohlspiegeln nach einem weiteren Ausführungsbeispiel der Erfindung.

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. The various embodiments are not limited to use in the specific form described, but can also be combined with each other.

Fig. 1

a plan view of an identification card with a security element according to the invention,

Fig. 2

schematically a cross section of the map of Fig. 1 along the line II-II,

Fig. 3

in (a) to (c) three embodiments of the invention, in which the optically variable recording layer is formed by a thin-film element with a color shift effect,

Fig. 4

a security element with a screened reflection layer according to an embodiment of the invention,

Fig. 5

a security element with a partially full area and partially rasterized reflection layer according to another embodiment of the invention, and

Fig. 6

a security element with a viewing element grid of a plurality of hollow micro-mirrors according to a further embodiment of the invention.

The invention will now be explained using the example of an identification card. 1 shows a schematic representation of an identification card 10 in the ID-1 format, which is provided with a security element 20 according to the invention. FIG. 2 schematically shows a cross section of the card 10 in the region of the security element 20 along the line II-II of Fig. 1 ,

For protection, the card 10 in addition to conventionally applied data 12 on an optically variable security element 20, which contains a tilting image of first and second markings 24, 26, which in Fig. 1 are schematically represented by the letters "AAA" and "BBB". Unlike in the graphic representation of Fig. 1 are the markings 24, 26 when viewing the card 10 not simultaneously, but only by tilting the card 10 in a different tilt angle 40,42 recognizable.

The markings 24, 26 of the tilt image are present in an optically variable recording layer 30, for example a thin-film element with a color-shift effect. In particular, the recording layer 30 includes a reflection layer formed by a vacuum vapor method, thereby allowing a tilting image to be easily and inexpensively introduced into the optically variable recording layer. With special advantage, the reflection layer is the reflector of a thin-film element with a color-shift effect.

The security element 20 further includes a viewing element grid 32 separated from the recording layer 30 by a spacer layer 28 and consisting of a plurality of parallel cylindrical lenses 34. The viewing element grid 32 is formed in the embodiment in the form of a horizontal lens grid, but it may be formed in other embodiments, for example, in the form of a vertical lenticular grid.

The thickness of the spacer layer 28 and the focal length of the cylindrical lenses 34 are matched to one another such that the markings 24, 26 of the recording layer 30 lie approximately in the focal plane of the lenses 34.

In an advantageous embodiment, the markings 24, 26 are written into the optically variable recording layer 30 after application of the lenticular screen 32 by means of a pulsed infrared laser. For this purpose, a laser beam from different directions 40 and 42 on the lenticular grid 32 directed. The cylindrical lenses 34 focus the laser beam depending on the direction of irradiation 40,42 on different portions of the optically variable recording layer 30 and generate there by the interaction of the laser radiation with the material of the recording layer 30, the desired markings 24,26. This interaction may, for example, consist in a local demetallization of the reflection layer and / or the absorber layer of a color-shifting thin-film element, as described with reference to FIG Fig. 3 explained in more detail below.

When viewing the finished card 10, the partial areas inscribed with this marking 24 can be seen from the viewing direction 40 because of the focusing effect of the cylindrical lenses 34 and, for a viewer, form the letters "A A A". Accordingly, from the viewing direction 42, the subregions inscribed in this direction can be recognized by the markings 26 and, for a viewer, are combined to form the letters "B B B". From the shallower viewing directions 44, 46, the cylindrical lenses each show only partial regions of the optically variable recording layer 30 which have not been modified by laser radiation and contain no markings.

Overall, the security element 20 thus has an optically double-variable appearance when viewed. The first optically variable effect is given by the tilting effect of the tilting image 24, 26. If the card is tilted from the viewing direction 44 via the viewing directions 40 and 42 to the viewing direction 46, the viewer first sees the recording layer 30 without marking (viewing direction 44), from the viewing direction 40, the first marking 24 and from the viewing direction 42 then the second marking 26 is visible, up to Finally, only the recording layer 30 without markings can be recognized again in the viewing direction 46.

The second optically variable effect is given by the optical variability of the recording layer 30 itself and depends on the type of the selected recording layer. The second optically variable effect is preferably a viewing-angle-dependent color-shift effect that conveys to the viewer a color impression that changes with the viewing direction. The color impression of the recording layer can, for example, change from green to blue, blue to magenta, or magenta to green when the security element is tilted.

FIG. 3 shows in (a) to (c) three embodiments of the invention, in which the optically variable recording layer is formed by a thin-film element 50 with color shift effect, which includes a reflective layer 52, an absorber layer 56 and a dielectric spacer layer 54 between the reflective layer and the absorber layer having.

In the embodiment of the Fig. 3 (a) The first and second markings 24, 26 are each formed by recesses 66 in the absorber layer 56 of the thin-film element 50. Such recesses 66 can be generated, for example, by laser application of the thin-film element 50 with relatively low laser energy. Looking at the security element of Fig. 3 (a) In plan view, the demetallized recesses 66 of the absorber layer 56 appear with no color shift effect with the color of the reflective layer 52, while the lying outside of the recesses 66 areas of the thin-film element 50 show the predetermined color shift effect.

For example, the markings 24, 26 formed by the demetallized recesses 66 when viewing the security element in plan view from the viewing direction 40 may be silvery glossy letter "AAA" and viewing direction 42 silver shiny letter "BBB" a color-shifting background. From other viewing directions 44, 46 neither the letters "A A A" of the marking 24 nor the letters "B B B" of the marking 26, but only the color-shifting background of the thin-film element 50 can be seen.

The security element of Fig. 3 (a) is designed for viewing in supervision, and in particular may be arranged in an opaque area of a card 10 or other data carrier.

In the embodiment of the Fig. 3 (b) For example, the first and second markings 24, 26 are respectively formed by recesses 62 in both the absorber layer 56 and the reflective layer 52 of the thin film element 50. Such recesses 62 can be generated, for example, by laser application of the thin-film element 50 with relatively high laser energy, so that not only the absorber layer 56 but also the reflection layer 52 is demetallized in certain areas.

Looking at the security element of Fig. 3 (b) In plan view, the demetallized recesses 62 of the absorber layer 56 and the reflection layer 52 appear colorless, while the areas of the thin-film element lying outside of the recesses 62 show the predetermined color-shift effect. Since the recesses 62 also extend through the reflective layer 52, they are visible not only in plan view, but also in view and then appear bright against the dark background of the opaque reflection layer 52.

For example, the markings 24, 26 formed by the demetallized recesses 62 when viewing the security element from the viewing direction 40 for an observer may be composed of the numbers "111" and from the viewing direction 42 to the numbers "2 2 2". In supervision, the numbers appear colorless in front of the color-shifting background of the thin-film element 50; in transmitted light they appear bright against the dark background of the reflection layer 52.

The security element of Fig. 3 (b) is designed to be viewed both in plan view and in transparency, and in particular may be arranged in a transparent or translucent window area or over an opening of a card 10 or other data carrier.

By a suitable variation of the laser parameters, for example the laser energy, it is also possible to produce two different tilt images for viewing in supervision and viewing, as in Fig. 3 (c) illustrated. There, first, by applying the thin-film element with low laser energy, recesses 66 were produced only in the absorber layer 56 of the thin-film element 50, which respectively form first partial identifications 24-A and 26-A of the markings 24, 26. Further, by applying the laser element to the thin-film element, recesses 62 were formed in both the absorber layer 56 and the reflective layer 52 of the thin-film element 50, respectively forming second indicia 24-B and 26-B of the indicia 24, 26.

Looking at the security element of Fig. 3 (c) In plan view, the demetallized recesses 66 of the absorber layer 56 without color shift effect appear with the color of the reflective layer 52, while the demetallized recesses 62 of the absorber layer 56 and the reflective layer 52 appear colorless. The lying outside of the recesses 62 and 66 areas of the thin-film element show the predetermined color shift effect. On the other hand, when viewed in phantom, only the recesses 62 that also extend through the reflective layer 52 are visible, as in FIG Fig. 3 (b) described. The security element of Fig. 3 (c) thus shows in supervision and review two different tilt images.

For example, the part markings 24-A, 26-A formed by the recesses 66 may complement the letters "AAA" from the viewing direction 40 and the letters "BBB" from the viewing direction 42, and the through-cutouts 62 from the viewing direction 40 to the numbers "111" and from the viewing direction 42 to the numbers "2 2 2".

In supervision, the viewer sees then formed by the recesses 66 part markings 24-A, 26-A with the color impression of the reflective layer 52 silvery shiny and formed by the continuous recesses 62 part markings 24-B, 26-B colorless, so takes on tilting of the security element, a tilting picture "A1 A1 A1" to "B2 B2 B2" before a farbkippenden background true, the letters each appear silvery shiny and the numbers appear colorless.

When viewed through the recesses 66 are present only in the absorber layer 56 can not be seen, while formed by the recesses 62 Part markings 24-B, 26-B appear bright against the dark background of the reflective layer 52. The observer therefore perceives a tilted image of bright numbers "111" after "2 2 2" against a dark background when the security element is tilted.

The reflective layer of the optically variable recording layer can not only be present over the full area outside the markings, as in US Pat Figures 2 and 3 but can also be screened there at least in some areas.

FIG. 4 shows a security element 70 with an optically variable recording layer in the form of a color-shifting thin-film element 72 with a rastered reflection layer 74, an absorber layer 56 and a dielectric spacer layer 54. The first and second markings 24, 26 are, similar to the embodiment of Fig. 3 (b) , formed by recesses 76 both in the absorber layer 56 and in the reflective layer 72 of the thin-film element 70.

In contrast to the embodiment of Fig. 3 (b) For example, the reflection layer 74 is scanned outside the markings 24, 26 and consists of a multiplicity of spaced raster elements 78. The security element 70 is therefore not opaque in transparency, even outside the markings, but weakly transparent. For example, the raster elements 78 may be formed in a circle with a diameter between 10 .mu.m and 100 .mu.m. The rasterization can be carried out in such a way that the raster elements 78 are visible in a direction-dependent manner, but that averaged over several lens diameters, a direction-independent transmittance of the reflection layer 74 is present. It has a stochastic distribution the raster elements 78 are found to be advantageous in order to avoid unwanted moiré effects.

In such an embodiment, the security element can also be combined with further, for example printed supervisory / review features, such as a vanishing in print information. The latter can also be provided on the back of the security element.

The reflection layer of the optically variable recording layer can also be partly full-surface and partially rastered. FIG. 5 shows a security element 80, which largely as the security element 70 of Fig. 4 is constructed. In contrast to this, the recording layer 72 of the security element 80 contains a reflection layer 82, which is present in the first partial regions 84 in a rasterized manner and in second partial regions 86 in a rasterized manner. The rasterized subregions 86 form a motif through their outline shape, which, due to the weak transparency of the rastered subregions 86, becomes visible in the light of the opaque background of the full-surface subregions 84. The security element 80 thus has, in addition to the optically doubly variable appearance, a supervisory / see-through effect, namely the motif of the screened subareas 86 appearing in the transmitted light. As a result of different sizes or spacings of the raster elements 78, this motif can also be formed with a plurality of gray levels become.

The markings 24, 26 can also be introduced into the recording layer in a different manner instead of the described laser application through the lenses 34, for example by demetallization of an absorber or reflection layer by a washing, etching, or Oil ablation. Also, optical ablation may be accomplished, for example, by patterning the recording layer over a high resolution mask with a single exposure.

As viewing elements, in addition to the previously described lenses 34, micro-hollow mirrors 92 may also be considered. Regarding Fig. 6 For example, a security element 90 comprises a grid of a plurality of hollow micro-mirrors 92 which are separated from the optically-variable recording layer 72 by a spacer layer 28.

The recording layer 72 must be at least partially transparent in this variant of the invention, which can be ensured, for example, by the use of a screened reflection layer 74. Furthermore, the recording layer 72 is to be arranged such that its optically variable effect is visible from the underside 96, that is to say the side facing the hollow micro mirrors 92, as in FIG Fig. 6 shown.

In a further variant of the invention, not shown, the optically variable effect is from the top side

In the variant of the invention with hollow micro-mirrors 92 as well, a motif can be inscribed in the optically variable recording layer 72 by means of laser exposure as described above, or the recording layer 72 can be structured by a washing, etching, or oil ablation process. Further, the reflector 94 of the micro-cavity mirror 92 can be designed as an optically variable layer and can be formed in particular by a color-shifting thin-film system. The reflector 94 of the micro-cavities 92 may also be partially or completely scanned to produce see-through effects. For the screening of the reflector 94 exist the same options as for the screened reflection layer 74, so that reference is made to the above statements. In particular, the screened areas of the reflector 94 may form a motif and / or make additional security features attached to the back of the security element 90 visible.

In further embodiments, the tilt images of the recording layer may exhibit an enlargement and / or depth effect as known from Moire Magnifier systems. The generation and properties of such micro-optical representational arrangements are, for example, in the international applications WO 2009/00528 A1 and WO 2006/087138 A1 described. When considering a security element according to the invention with moiré magnification effect, a marking is then to be seen below the respective tilt angle which, depending on the embodiment, seems to float in front of or behind the plane of the security element.

Claims (12)

1. An optically variable security element for safeguarding data carriers having a shift image consisting of first and second markings which are recognizable from different first or second viewing directions, wherein the first and second markings of the shift image are present in an optically variable recording layer which has a reflective layer produced by a vacuum deposition method, wherein the security element contains a viewing element grid spaced from the recording layer and showing the first or second markings upon viewing from the first or second viewing direction, wherein the optically variable recording layer contains a thin-film element having a color-shift effect, and wherein the thin-film element has a reflective layer, an absorber layer and a dielectric spacer layer arranged between the reflective layer and the absorber layer, characterized in that the first and/or second markings are formed by gaps in the absorber layer and/or in the reflective layer and/or in the dielectric spacer layer and respectively comprise first and second partial markings, wherein the first partial markings are formed by gaps only in the absorber layer and the second partial markings are formed by gaps both in the absorber layer and in the reflective layer, so that the security element shows different shift images in plan view and transmission view, that the reflective layer of the optically variable recording layer is gridded outside the markings at least in partial regions and consists in said partial regions of a multiplicity of grid elements which are formed by gaps in a substantially opaque layer, or by substantially opaque, spaced pattern base elements, and that the gridded partial regions form a motif in the form of patterns, characters or an encoding.
2. The security element according to claim 1, characterized in that the first and second markings are incorporated into the optically variable recording layer through the viewing element grid by laser radiation from different directions.
3. The security element according to at least one of claims 1 to 2, characterized in that the first and second partial markings are incorporated into the optically variable recording layer through the viewing element grid by laser radiation with different laser energy.
4. The security element according to at least one of claims 1 to 3, characterized in that the reflective layer of the optically variable recording layer is present over the full area at least outside the markings.
5. The security element according to at least one of claims 1 to 4, characterized in that the grid elements are arranged stochastically.
6. The security element according to at least one of claims 1 to 5, characterized in that the grid elements are configured to be circular, preferably with a diameter between 10 µm and 100 µm, or line-shaped, preferably with a width of 30 µm to 70 µm
7. The security element according to at least one of claims 1 to 6, characterized in that the viewing element grid is formed from a plurality of microlenses, in particular cylindrical lenses or spherical lenses, or from a plurality of concave micromirrors.
8. The security element according to at least one of claims 1 to 7, characterized in that the optically variable recording layer is separated from the viewing element grid by a transparent spacer layer.
9. A method for manufacturing an optically variable security element according to at least one of claims 1 to 8, wherein

   - an optically variable recording layer is manufactured with a reflective layer produced by vacuum deposition,

   - first and second markings are incorporated into the optically variable recording layer,

   - the optically variable recording layer is combined in a spaced manner with a viewing element grid which, upon viewing from different first or second viewing directions, shows the first or second markings, so that the first and second markings form a shift image,

   - the optically variable recording layer is manufactured with a thin-film element having a color-shift effect, wherein the thin-film element has a reflective layer, an absorber layer and a dielectric spacer layer arranged between the reflective layer and the absorber layer; characterized in that

   - the first and/or second markings are formed by gaps in the absorber layer and/or in the reflective layer and/or in the dielectric spacer layer and respectively comprise first and second partial markings,

   - the first partial markings are formed by gaps only in the absorber layer and the second partial markings are formed by gaps both in the absorber layer and in the reflective layer, so that the security element shows different shift images in plan view and transmission view,

   - the reflective layer of the optically variable recording layer is gridded outside the markings at least in partial regions and is formed in said partial regions from a multiplicity of grid elements which are formed by gaps in a substantially opaque layer, or by substantially opaque, spaced pattern base elements, and

   - the gridded partial regions are formed by a motif in the form of patterns, characters or an encoding.
10. The method according to claim 9, characterized in that the first and second markings are incorporated into the optically variable recording layer through the viewing element grid by laser radiation from different directions.
11. The method according to claim 9, characterized in that the first and second markings are incorporated into the optically variable recording layer by a washing, etching, or oil ablation method.
12. A data carrier, in particular security paper or value document, having a security element according to any of claims 1 to 8.

Images