METHOD FOR THE PRODUCTION OF A SECURITY FEATURE, SECURITY FEATURE FOR A DATA MEDIUM, DATA MEDIUM, AND LAMINATION SHEET

Abstract

A method for producing a security feature for a data medium, includes the steps of: providing a molding means having a molding structure of a representation of the security feature; introducing the representation into a substrate by impressing the molding structure; and arranging a light-diffractive or light-refractive structure on the substrate.

Claims

1.-15. (canceled)

16. A method for producing a security feature for a data medium, comprising the steps of: providing a substrate which is transparent or partially transparent in the visible spectral range; providing a molding means which has a molding structure and forms an image presentation of a representation which together with a light-diffractive or light-refractive structure generates an optically variable image; introducing the representation into one side of the substrate by impressing the molding structure; and forming a light-diffractive or light-refractive structure on the opposite side of the substrate.

17. The method as claimed in claim 16, wherein the molding means is a lamination sheet and the representation is introduced during lamination of the substrate.

18. The method as claimed in claim 17, wherein the light-diffractive or light-refractive structure is disposed on the substrate during lamination by means of a second lamination sheet and the steps of introducing the representation into one side of the substrate by impressing the molding structure and forming a light-diffractive or light-refractive structure on the opposite side of the substrate are carried out in a common laminating process.

19. The method as claimed in claim 16, further comprising the step of: introducing a superimposed security element into the substrate with a laser by changing the substrate material locally in terms of color.

20. The method as claimed in claim 16, wherein the introduction of the superimposed security element takes place through the light-diffractive or light-refractive structure.

21. The method as claimed in claim 16, wherein the substrate has at least one laser-sensitive layer and the superimposed security element is formed in this layer.

22. The method as claimed in claim 16, wherein the introduction of the superimposed security element takes place after the production of the first security feature.

23. The method as claimed in claim 16, wherein the molding structure is introduced into the molding means with a laser cutting, milling, water jet cutting or a galvanic method.

24. The method as claimed in claim 16, wherein elements of the molding structure are calculated such that the representation is a moving representation when the security feature is tilted.

25. The method as claimed in claim 16, wherein the molding means is a stamp and in that the representation is introduced after lamination of the substrate.

26. A security feature for a data medium, having a substrate which is transparent or partially transparent in the visible spectral range and in which a representation has been molded which together with a light-diffractive or light-refractive structure generates an optically variable image, and having a light-diffractive or light-refractive structure formed on the substrate, which structure at least partially covers the representation and interacts with it in order to generate a moving representation when the security feature is tilted.

27. A data medium, such as a value document or a chip card, comprising a carrier on or in which a security feature as claimed in claim 16 is arranged.

28. A data medium, such as a value document or a chip card, comprising a carrier on or in which a security feature as claimed in claim 19 is arranged, further comprising the superimposed security element.

29. A lamination sheet for the production of a security feature for a data medium, having a molding structure which is an image presentation of a representation which together with a light-diffractive or light-refractive structure generates an optically variable image.

30. The lamination sheet as claimed in claim 29, wherein the molding structure is introduced into the molding means with a laser cutting, milling, water jet cutting or a galvanic method.

Description

BRIEF DESCRIPTION OF THE DRAWINGS

[0035] The present invention is described by way of example below, with reference being made to the attached drawings, in which:

[0036] FIG. 1 shows a top view of a data medium with a security feature;

[0037] FIG. 2 shows a sectional illustration of the data medium of FIG. 1 according to the line I-I;

[0038] FIG. 3 shows an example of a moving representation;

[0039] FIG. 4 shows a section through an alternate embodiment of the data medium;

[0040] FIG. 5 shows an embodiment of the security feature with a superimposed security element;

[0041] FIG. 6 shows an example of a moving representation with a superimposed security element;

[0042] FIG. 7 shows a basic illustration of a production of a security feature;

[0043] FIG. 8 shows an added-value production of security features;

[0044] FIGS. 9A and 9B show a basic illustration of lamination sheets for the production of a security feature; and

[0045] FIG. 10 shows a method for producing a security feature for a data medium.

DETAILED DESCRIPTION OF THE INVENTION

[0046] FIG. 1 shows a top view of a data medium 1 in a schematic illustration. The data medium 1 may be a value document in the form of a banknote, a passport and identity document or the like. Likewise, the data medium 1 may be a chip card. In the example shown in FIG. 1, the data medium 1 is an identity document.

[0047] The data medium 1 contains a security feature 11, which generates a visually checkable optically variable image, for example a symbol. The optically variable image is a moving image or a tilting image. The security feature 11 is at least partially arranged in a region 1 of the data medium 1 in which the latter is transparent or partially transparent in the visible spectral range.

[0048] The data medium 1 contains further person-related data 12, for example the first and last name of the owner. Moreover, the identity card may contain further data 13, for instance date of birth, nationality, issuing authority, date of issue and the like.

[0049] The basic structure of the security feature 11 will now be explained in detail with reference to FIG. 2, which shows a section through a first embodiment of the data medium 1 along the line I-I in FIG. 1.

[0050] The data medium 1 forms a substrate 10, which is transparent or partially transparent in the visible spectral range, for the security feature 11. In the embodiment according to FIG. 2, the substrate 10 consists of a card body 14 which is transparent or partially transparent in the visible spectral range and of the security feature 11, which is at least partially arranged in an opening la in the data medium 1 or the card body 14. The card body 14 may in principle also be opaque, in which case a transparent or partially transparent portion is provided in the region of the security feature 11.

[0051] The security feature 11 comprises a carrier element 15 which is transparent or partially transparent in the visible spectral range and into which a representation 16 is molded. The representation 16 is introduced in the form of a surface relief on one side, here a bottom side or back side, of the carrier element 15.

[0052] On an opposite side of the carrier element 15, here an upper side or front side, a light-diffractive or light-refractive structure 17 is arranged, which at least partially covers the security feature 11 or the representation 16.

[0053] The carrier element 15 may contain or consist of phosphorescent fluorescent or phosphorescent materials. The same applies to any further layers or extruded films which may be present and which are a constituent part of or interact with the security feature 11.

[0054] The light-diffractive or light-refractive structure 17 is expediently a surface relief in the form of a lens array; such an embodiment will in the following text always be based on the following. Expediently, a lens array 17 with individual lenses such as ball lenses, rod lenses and/or cylindrical lenses is used. The lens array 17 is arranged on the upper side of the carrier element 15 relative to the representation 16 and can be directly connected to the carrier element 15. The carrier element 15 is thus located between the lens array 17 and the representation 16.

[0055] The representation 16 has been calculated in adaptation to the lens array 17 prior to the introduction into the carrier element 15 such that, when viewing through the lens array 17, a moving representation is produced when tilting the security feature 11 or the data medium 1. For example, the moving representation can be a tilting image that tilts or changes between two or more representations when the representation 16 is moved relative to the view of the viewer. For example, the moving representation can also be a movement across multiple images. These images can be represented as moving in an endless movement.

[0056] An example of a moving representation 16 is shown in FIG. 3. In the example shown, when tilting the security element 11, an observer sees a movement of the forelegs of a horse. In order to achieve the impression of movement, the representation is divided into a plurality of individual elements, which are perceived through the lens array 17 in dependence on the viewing angle. The representation 16 may include, for example, a security feature based on a moir effect, the fundamentals of which, for example, are set out in EP 2162294 B1.

[0057] Due to the fine structure of the representation 16, a multiplicity of images can be generated, since the distance between two optical structures such as a lens usually stipulates the number of images. This distance, also known as pitch, is used as a parameter in the calculation of the representation 16. One image per pitch can be provided. As part of a data preparation process before the introduction of the representation 16, the number of images is mathematically included in this representation 16.

[0058] The images contained in the representation 16 can be graphical representations, such as rotating gears, text elements, and pictorial representations. The representation may also contain personal information, such as a name, signature, date of birth or the like. In addition, the representation 16 may include data relating to the data medium 1, such as a validity period, a card number, an indication of the issuing authority or the like.

[0059] The data medium 1 may comprise additional layers, for example one or more protective layers or functional layers provided with other security elements. In this case, the transparency of the data medium 1 in the region of the security feature 11 can be maintained. This allows the security feature 11 to be viewed both from the front side and from the back side of the data medium 1.

[0060] Due to the calculated interaction between the representation 16, or its individual elements, and the lens array 17, a viewer sees the viewing-angle-dependent representation 16 when they look at the data medium 1 from the front side or the back side. If the data medium 1 with the representation 16 is swiveled or tilted, a movement of the representation 16 becomes visible, which is generated by the calculated interaction of the representation 16 with the light-diffractive or light-refractive structure 17.

[0061] FIG. 4 shows a section through an alternative embodiment of the data medium 1 along the line I-I of FIG. 1. The data medium 1 forms in the region of the security feature 11 in turn a substrate 10 which is transparent or partially transparent in the visible spectral range. The data medium 1 has a multi-layer layer structure, which is designed to be consistently transparent or partially transparent in the visible spectral range in the region in which the security feature 11 is arranged. The data medium 1 is based on a central carrier layer 18, in which a partial region 19 which is transparent or partially transparent in the visible spectral range is formed in the region of the security feature 11. The transparent partial region 19 may be a transparent insert 19, which is arranged in an opening 1a. The remaining part of the central carrier layer 18 may be opaque or likewise transparent.

[0062] On one side of the carrier layer 18, an upper layer 15 which is transparent or partially transparent in the visible spectral range and which forms a carrier element for the lens array 17 is arranged. On the opposite side of the carrier layer 18, a second upper layer 25 which is transparent or partially transparent in the visible spectral range is arranged. The representation 16 is molded in the form of a surface relief in the external side of said upper layer. Between the central carrier layer 18 and the upper layers 10, 25, further intermediate layers 18a, 18b which are transparent or partially transparent in the visible spectral range can be arranged.

[0063] Depending on the viewing angle, as indicated in FIG. 4, a viewer sees another aspect of the representation 16 when viewing the representation 16 through the lens array 17. For example, if the representation has the shape of a running horse, the horse appears in two different states of motion when changing between the viewing angles.

[0064] FIG. 5 shows a preferred configuration of the security feature 11. In addition to the lens array 17 and the moving representation 16, a superimposed security element 26 is introduced into the substrate 10 with a laser. The introduction of the superimposed security element 26 takes place by the material of the substrate 10 being changed locally in terms of color by the input of laser energy. In an expedient manner, the local color change is effected by generating black or dark surface elements 27 in a layer of the substrate 10, as indicated in FIG. 5. The laser energy input L is preferably realized through the lens array 17, as indicated in FIG. 5. The substrate 10 expediently consists of at least two layers 10, 18, 18a, 18b, 25, of which at least one-indicated by small circles Dis doped such that it becomes laser-sensitive. The remaining layers of the substrate 10 are preferably laser-transmissive. In the layer 18a which is laser-sensitive due to doping, the local color change is configured as a superimposed security element 26 owing to the laser energy input Lfor example with an NdYAG laser with 1064 nm.

[0065] The superimposed security element 26 can be a symbol, a free form, a sequence of alphanumeric characters, or an illustration. It can be data-medium-specific or standardized.

[0066] FIG. 6 shows a moving representation 16 as an example of a security feature 11 with a superimposed security element 26, in which an alphanumeric piece of information 26 is introduced as a superimposed security element.

[0067] The superimposed security element 26 is also optically variable when viewed through the lens array 17. Depending on the viewing angle through the lens array 17, another version of the superimposed security element 26 appears, or the security element 26 is recognizable or not.

[0068] In addition, as indicated in FIG. 5, the superimposed security element 26 is always recognizable when viewed from the side opposite the lens array 17, i.e. from the side carrying the representation 16, regardless of the viewing angle.

[0069] In one variant, the laser energy input for forming the superimposed security element 26 can also be carried out from the side of the substrate 10 opposite the lens array 17. The superimposed security feature 26 then shows no or only a slightly pronounced optically variable effect when viewed through the lens array 17.

[0070] FIG. 7 shows a basic illustration of a production of a security feature by means of a laminating device 20. The laminating device 20 is only shown in principle. In particular, means for generating pressure and/or an increased temperature are not shown.

[0071] Two lamination sheets 21 and 22 are shown, between which the substrate 10 is laminated. The substrate 10 is present in the form of a sheet of material or a film. The substrate 10 is placed between the two lamination sheets 21 and 22. The two lamination sheets 21 and 22 are then moved toward the substrate 10 to build up pressure thereon. In this case, a temperature increase is usually carried out in order to melt or at least heat the plastics material of the substrate 10 or the layer structure.

[0072] In the lamination sheet 21, a multiplicity of light-diffractive or light-refractive structures, which form, for example, a reversed lens array, are incorporated as an image presentationdepending on the molding technique being selected as a negative mold or as a positive mold or as a mixture of negative and positive molds-in the form of openings 21a.

[0073] During laminating, the individual light-diffractive or light-refractive structures are formed in the substrate 10 by impression of the openings 21a and form a lens array 17 there, for example. The light-diffractive or light-refractive structures 17 are thus fixedly connected to the substrate 10.

[0074] In the opposite lamination sheet 22, the molding structures 23 of the representation 16 are incorporated as an image presentation. The shape and relative position of the molding structures 23 were determined mathematically. The molding structures 23 correspond as a relief to a two-dimensional printed pattern. It has been shown that molding structures formed in the shape of a relief 23 achieve the same effect as a corresponding printed pattern.

[0075] The molding structures 23 of the security feature have been introduced into the lamination sheet 22, for example, by means of a laser cutting, milling, water jet cutting or a galvanic method.

[0076] Before the introduction of the molding structures 23 into the lamination sheet 22 and before the production of the light-diffractive or light-refractive structures 17, these have each been calculated as a function of one another. Thus, a moving representation of the representations 16 can be achieved with changing viewing angles.

[0077] During laminating, the lens array 17 is molded into the substrate 10 on one side of the substrate 10 and the representation 16 is simultaneously formed on the other side. In this way, the security feature 11 is created in the substrate 10. The lens array 17 and the representation 16 are thereby fused with the substrate 10 and part of the substrate 10, so that both are fixedly connected to the substrate 10.

[0078] FIG. 8 shows a laminating arrangement for added-value manufacturing of security elements 11. Two lamination sheets 21 and 22 are shown, between which the substrate 10 lies as a sheet of material or film.

[0079] A plurality of lens arrays 17 are incorporated into the lamination sheet 21, as a negative or, according to the imaging technique, optionally also as a positive or as a mixture of both. A corresponding plurality of molding structures 23 of the representation 16 are introduced as image presentations into the opposite lamination sheet 22.

[0080] In the substrate 10, a plurality of security features 11 is formed in a laminating process. The substrate 10 is moved between the two lamination sheets 21 and 22. The two lamination sheets 21 and 22 are then moved toward the substrate 10 to build up pressure on the latter there. In this case, a temperature increase is usually carried out in order to melt or at least heat the plastics material of the substrate 10.

[0081] FIGS. 9 show a basic illustration of lamination sheets for the production of a security feature.

[0082] FIG. 9a shows a basic illustration of the lamination sheet 22 with the multiplicity of molding structures 23 of the representations 16. The molding structures 23 are arranged on the lamination sheet 22 such that a region in the size of the later security feature or the size of the later data medium remains free around each molding structure 23.

[0083] FIG. 9b shows the second lamination sheet 21 with the light-diffractive or light-refractive structures 17, which are arranged in each case in an opening 21a. The openings 21a and thus the light-diffractive or light-refractive structures 17 are arranged at identical positions as the molding structures 23 on the lamination sheet 22. Thus, it is ensured that the light-diffractive or light-refractive structures 17 are aligned with the representation 16 at the security feature to be produced. In this case, the spatial extents of the light-diffractive or light-refractive structures do not have to be identical to those of the representations 16.

[0084] FIG. 10 shows a method for producing a security feature 11 for a data medium 1. In a first step 10, a molding means, such as a lamination sheet 22, is provided with a molding structure 23 of a representation 16 of the security feature 11. As previously shown, a multiplicity of molding structures 23 may be provided on the molding means. The molding structure 23 can be introduced into the molding means, for example, with a laser cutting, milling, water jet cutting or a galvanic method.

[0085] In a second step 11, the representation 16 is introduced into the substrate 10 by impressing the molding structure 23. This is preferably done during the lamination of the security feature 11 or the substrate 10. In this case, the molding structure 23 is embossed or pressed into the plastics material of the substrate 10 with pressure and under the influence of heat. The resulting representation 16 comprises or consists of recesses in a surface of the substrate 10.

[0086] In a third step 120, a light-diffractive or light-refractive structure 17 is arranged on the substrate 10. The light-diffractive or light-refractive structure 17 can, for example, be fused with the substrate 10 or be connected by means of an adhesive.

[0087] The sequence of steps is not necessarily limited to this sequence. For example, the arrangement of a light-diffractive or light-refractive structure 17 can also be carried out as a first or second step. In particular, the arrangement of a light-diffractive or light-refractive structure 17 on the substrate 10 and the introduction of the representation 16 into the substrate 10 can be carried out in a common laminating process using a second lamination sheet 21.

[0088] This method can be used to produce the previously described security feature 11. The previously described lamination sheets 21 and 22 or only the lamination sheet 22 can be used here.

[0089] While retaining the basic idea, the above-described invention allows for a variety of further configurations and modifications. In particular, the described elements can be arranged in compositions other than those described. The figures and the associated descriptions should not be understood to mean that precisely only the described embodiments can be realized within the scope of the invention.