Abstract:
An optically variable element, in particular an optically variable safeguard element for safeguarding banknotes, credit cards and the like. A security product and a foil, in particular an embossing foil or a laminating foil, having such an optically variable element. The optically variable element has a thin film for producing color shifts by means of an interference and/or a reflective layer. The optically variable element further has a transparent window. The interference film and/or the reflective layer include a partial element, namely a partial thin film element or a partial reflective element, respectively. The partial element or elements surround the surface region of the transparent window.

Description:
CROSS-REFERENCE TO RELATED APPLICATIONS 
     This application is a National Phase application of International Application No. PCT/EP03/04022 filed Apr. 17, 2003, which claims priority based on European patent application No. 02010729.8 filed on May 14, 2002, which are incorporated herein by reference. 
     BACKGROUND OF THE INVENTION 
     The invention concerns an optically variable element, in particular an optically variable security element for safeguarding banknotes, credit cards and the like, which has a thin film for producing color shifts by means of interference and/or a reflective layer. The invention further concerns a security product and a foil, in particular an embossing foil or a laminating foil, which has such an optically variable element. 
     Optically variable elements are frequently used to make it difficult to copy and misuse documents or products and if possible to prevent that from happening. Optically variable elements are frequently used for safeguarding documents, banknotes, credit cards, cash cards and the like. 
     In order to make it difficult to copy optically variable elements, it is known for an optically variable element to be provided with a thin film layer succession which produces color shifts by means of interference, in dependence on the viewing angle. 
     WO 01/03945 A1 describes a security product having a transparent substrate, to one side of which is applied a thin film which produces a perceptible color shift in dependence on the change in the angle of view. The thin film comprises an absorption layer which is applied to the transparent substrate and a dielectric layer which is applied to the absorption layer. The absorption layer includes a material which is made up from one of the following materials or a combination of those materials: chromium, nickel, palladium, titanium, cobalt, iron, tungsten, molybdenum, iron oxide or carbon. The dielectric layer comprises one of the following materials or a combination of the following materials: silicon, aluminum oxide, magnesium fluoride, aluminum fluoride, barium fluoride, calcium fluoride or lithium fluoride. 
     In order further to increase the level of safeguard against copying, a diffraction pattern is embossed on the side of the transparent substrate, which is in opposite relationship to the thin film layer succession. That diffraction pattern acts as a diffraction grating so that for example the illusion of a three-dimensional image can be produced for the viewer, by means of that two-dimensional pattern. 
     It is further proposed that the diffractive pattern be applied by embossing to the side of the transparent substrate to which the thin film layers are also applied. 
     Those two embodiments of an optically variable element provide that, at each location of the optically variable element, the optical effects produced by the thin film layers and the optical effects produced by the diffractive pattern are superimposed and this therefore overall affords an optical effect which is difficult to imitate and copy. 
     The invention is now based on an optically variable element as is described in WO 02/00445 A1. 
     The optically variable element comprises here a plurality of layers which are arranged generally in mutually superposed relationship. The optically variable element has on the one hand a thin film which produces the optical effect, already described above, of a color change which is dependent on the angle of view. In addition the optically variable element has a replication layer into which a relief structure is embossed. That relief structure produces a further optical effect, namely the diffraction effect which has already been described hereinbefore and by means of which holograms and the like can be represented. In that respect, in regard to production procedure, firstly the thin film layers are applied to the replication layer and then the relief structure is embossed thereon. 
     As an alternative thereto, WO 02/00445 A1 describes that the optical effect produced by the thin film structure and the optical effect produced by the relief structure are decoupled from each other. Two operating procedures are proposed for that purpose. 
     On the one hand it is proposed that an opaque layer is applied between the relief structure which produces a holographic image by means of diffraction and the thin film which produces a color change effect. The relief structure is screened from the thin film structure by means of that opaque layer. The second possible option involves arranging two or more layers of a substantially transparent material between the relief structure producing a holographic image by diffraction and the thin film layers. Those layers can include one or more highly refractive layers and an adhesive layer. Those layers provide for an increase in reflection and thus the strength of light in the region of the relief structure producing a holographic image. 
     In this respect, such a variable optical element can be produced as follows: firstly a pattern is embossed into a holographic foil. That foil is then provided in region-wise manner with a metal layer. The thin film layers are then vapor-deposited in succession. Lastly, a metal layer is applied, over the full surface area. 
     A further possible option involves providing a prefabricated thin film layer succession with an embossable lacquer and then embossing the relief structure into that lacquer. It is further proposed that such prefabricated thin film layers can be glued to prefabricated microstructures. 
     WO 02/00445 A1 thus describes either using security elements in which the optical effect produced by diffractive structures and the optical effect produced by thin film structures are coupled together, or using security elements in which the optical effect produced by diffractive structures and the optical effect produced by thin film layers are decoupled from each other. 
     SUMMARY OF THE INVENTION 
     Now, the object of the invention is to make it difficult to imitate and copy optically variable elements and thus to improve the anti-forgery security of security products. 
     That object is attained by an optically variable element, in particular an optically variable safeguard element for safeguarding banknotes, credit cards and the like, which has a thin film for producing color shifts by means of interference and/or a reflective layer, wherein the optically variable element has a transparent window and the thin film and/or the reflective layer is respectively in the form of a partial element, namely a partial thin film element or a partial reflective layer, wherein the partial element or elements surround the surface region of the transparent window. That object is further attained by a security product and a foil, in particular an embossing foil or a laminating foil, which has such an optically variable element. 
     The invention achieves the advantage that an optically variable element according to the invention is substantially more difficult to copy than the optically variable elements known in the state of the art. As a result, the anti-forgery security of security products provided with an optically variable element of the configuration according to the invention is considerably increased. In particular the level of anti-forgery security is far increased in that respect in comparison with surface elements of a sandwich-like structure. 
     Thus for example the optically variable element described in WO 02/00445 A1—as described in WO 02/00445 A1 as a possible mode of manufacture—can be imitated by a prefabricated thin film foil being processed with an embossing stamp, with which a diffractive structure is embossed into the thin film foil. That is no longer possible with an optically variable element designed in accordance with the invention: the partial application of a partial window which is surrounded by a partial reflective layer and/or a partial thin film element requires a high level of technology complication and expenditure. In comparison with a prefabricated thin film foil the partial thin film element produced in that way represents an individualised element so that imitation of the optically variable element is no longer possible, starting from a prefabricated thin film layer succession. 
     Further advantages in relation to previous individual representations or mutually superposed surface elements lie in better optical integration into the overall element to be protected, the existence of the possibility of making patterns, texts and codes arranged under the optically variable element specifically and targetedly usable and thus providing an additional security feature, the specifically targeted geometrical arrangement of functional windows (machine-readability, personal data and so forth) and the choice, which can be better matched, in respect of the physical-chemical properties of the partially arranged individual elements (corrosion, intermediate layer adhesion and the like). 
     Advantageous configurations of the invention are set forth in the appendant claims. 
     It is desirable if the optically variable element has one or more further layers which extend over the surface region of the transparent window and over the surface region of the partial thin film element and/or the partial reflective layer. Thus the optically variable element preferably has a replication layer, a protective lacquer layer and/or an adhesive layer which extends over the surface region of the transparent window and over the surface region of the partial thin film element and/or the partial reflective layer. In that case the layers may also involve the full surface area. 
     The level of anti-forgery security can be increased if a diffractive structure, in particular for producing diffraction effects, is applied in the surface region of the transparent window. For example holograms can be produced by means of such a diffractive structure. It is possible for that diffractive structure to occupy the total surface region of the transparent window. Imitation of that security feature is made difficult however if the diffractive structure occupies only a part of the surface region of the transparent window and thus forms a partial diffractive element, in relation to the transparent window. That partial application means that inaccuracies in register relationship, which under some circumstances can cause a blur effect in the boundary region between the transparent window and the surrounding partial elements, are more easily discernible to the viewer. 
     Imitation of the optically variable element is made further considerably more difficult if the optically variable element is provided with a diffractive structure which extends both over a surface region of the transparent window and also over a surface region of the partial thin film element and/or the partial reflective layer. Thus the diffractive structure extends over the boundary line between the transparent window and the surrounding partial element or elements. If, in an attempt at imitation, the attempt is made to use an embossing stamp to emboss a diffractive structure extending over that boundary line, the diffractive structure is embossed to a differing depth by virtue of the differing layer structure of those different partial elements (transparent window, partial reflective layer, partial thin film element). In that way at least the boundary line within the hologram represented by the diffractive structure, becomes discernible, for example due to a fault occurring in the hologram. Thus such an attempt at imitation can be clearly perceived by the viewer and can be identified as a forgery. 
     That effect can be increased if there are differences in level between the surface region of the transparent window and that of the reflective layer and/or that of the partial thin film element, that is to say the optically variable element in those surface regions is of a different overall layer thickness. That effect can also be enhanced by virtue of the choice of the materials selected in those regions (for example differing hardness) and by virtue of the layer composition. 
     It is advantageous if the transparent window has a partial transparent element with specific optical properties. That provides that different partial elements (partial transparent element, partial thin film element, partial reflective layer) follow each other. As already indicated above, that makes it difficult to imitate the optically variable element in relation to the known optically variable security elements which are of a sandwich-like structure. The partial transparent element, as an additional security feature, can have a colored transmission layer or can have scattering properties. 
     A possible way, which enjoys production-engineering advantages, of designing a partial transparent element, involves applying an absorption layer but no spacer layer in the surface region of the partial transparent element, that is to say in the transparent window. Those advantages are further also achieved if a spacer layer but not an absorption layer is applied in the surface region of the partial transparent element. 
     It is desirable for the partial thin film element to be made up of an absorption layer and a spacer layer. It is further possible for the partial thin film element to be made up from a relatively large number of layers which have alternately different refractive indices. 
     The level of anti-forgery security can be further increased by the partial thin film layer having a reflective layer, preferably a metal layer. That improves the recognisability of the partial thin film element. 
     Alternatively there is also the possibility of providing the partial thin film element with a transmission layer. In that case it is particularly advantageous for that transmission layer to be colored and thus to provide an additional security feature. 
     Imitation of the optically variable element can be made still more difficult if the partial thin film element is provided with a partial reflective layer, in particular a metal layer, which only partially covers the surface region of the partial thin film element. Besides the increase in the level of anti-forgery security that this entails, that also makes it possible to achieve attractive decorative effects. That therefore increases the array of shapes available for the design configuration of an optically variable element. 
     These advantages can be achieved by the partial thin film element being provided with a partial diffractive structure which only partially covers the surface region of the partial thin film element. 
     Those two measures, namely the partial reflective layer and the partial diffractive layer, can also be embodied in parallel. 
     It is possible for the configurational elements ‘partial transparent element with partial reflective layer’, ‘partial transparent element with partial diffractive structure’, and ‘partial transparent element with partial thin film structure’ to be combined together as desired. An optically variable element according to the invention can thus have a plurality of combinations of valuable security features and affords a large number of attractive configurational features. 
    
    
     
       BRIEF DESCRIPTION OF THE DRAWINGS 
       The invention is described hereinafter by way of example by means of a number of embodiments with reference to the accompanying drawings in which: 
         FIG. 1  shows a view in section through an optically variable element, 
         FIG. 2   a  shows a view of an optically variable element according to the invention, in a first embodiment, 
         FIG. 2   b  shows a view of an optically variable element according to the invention, in a second embodiment, 
         FIG. 2   c  shows a view of an optically variable element according to the invention, in a third embodiment, 
         FIG. 3  shows a view in section through an optically variable element according to the invention for a further embodiment of the invention, 
         FIG. 4  shows a view in section through an optically variable element according to the invention for a further embodiment of the invention, 
         FIG. 5   a  shows a view in section through an optically variable element according to the invention for a further embodiment of the invention, 
         FIG. 5   b  shows a view in section through an optically variable element according to the invention for a further embodiment of the invention, 
         FIG. 6  shows a view in section through an optically variable element according to the invention for a further embodiment of the invention, and 
         FIG. 7  shows a view in section through an optically variable element according to the invention for a further embodiment of the invention. 
     
    
    
     DETAILED DESCRIPTION OF THE INVENTION 
       FIG. 1  shows the structure in principle of an optically variable element  0 . 
     The optically variable element  0  is intended to be applied to a security product, for example a banknote, a credit card, a cash card or a document. There is also the possibility that the optically variable element is intended to be applied as a security or authenticity identification to an article, for example to a CD, or to a packaging. 
     The optically variable element  0  can assume many different forms. The optically variable element  0  can thus be for example a security thread which is intended to be applied to one of the above-specified objects. 
       FIG. 1  shows a carrier  1  and five layers  2  through  6 . The optically variable element  0  is formed by the layers  2  through  6 . The layer  2  is a protective lacquer and/or release layer, the layer  3  is an absorption layer, and the layer  4  is a spacer layer. The layer  5  is a metal layer or an HRI layer (HRI=High Refractive Index). The layer  6  is an adhesive layer. 
     The carrier  1  comprises for example PET. The carrier serves for producing the optically variable element, from the production-engineering point of view. Upon or after application of the optically variable element to the object to be safeguarded, the carrier  1  is removed.  FIG. 1  therefore shows the optically variable element at a stage in which it is part of a foil, for example an embossing foil or a laminating foil. 
     In the case where the optically variable element  0  is part of a laminating foil, the layer  2  has a bonding layer. 
     In principle, a thin film is distinguished by an interference layer structure which produces color shifts which are dependent on the viewing angle. It can be in the form of a reflective element, with for example highly reflective metal layers, or in the form of a transmissive element with a transparent optical separation layer of higher refractive index (HRI) or lower refractive index (LRI), in relation to the adjoining layers. The base structure of the thin film has an absorption layer (preferably with between 30% and 65% transmission), a transparent spacer layer as a color change-producing layer (for example λ-quarter or λ-half layer) and a metal layer as a reflective or an optical separation layer as a transmitting layer. 
     The layers  3 ,  4  and  5 , that is to say the absorption layer, the spacer layer and the metal layer or HRI layer form a thin film which produces color shifts dependent on the viewing angle, by means of interference. In that respect, the color shifts produced by the thin film are preferably in the range of the light which is visible to a human viewer. In addition that thin film is in the form of a partial thin film element which covers the surface region of the optically variable element  0  only in a region-wise and pattern-shaped manner. 
     If the layer  5  comprises a reflective layer, for example aluminum, then the layer thickness of the spacer layer  4  is to be so selected that the λ/4 condition is satisfied. If the layer  5  comprises a transmissive layer then the spacer layer  4  has to satisfy the λ/2 condition. 
     It is possible for the partial thin film element to be made up of a succession of high-refractive and low-refractive layers. For example the partial thin film element can be made up of between 3 and 9 such layers (odd number of thin film layers) or between 2 and 10 such layers (even number of thin film layers). The higher the number of layers, the more sharply can the wavelength be set for the color change effect. 
     Examples of usual layer thicknesses for the individual layers of the partial thin film element and examples of materials which can be used in principle for the layers of the partial thin film element are disclosed in WO 01/03945, page 5, line 30 through page 8, line 5. 
     The layer  5  can be in the form of a partial metal layer or an HRI layer. The materials for the layer  5  can be for example Al, Ag, Cr, Cu, Au or combinations of those metals. 
     It is further possible for the layer  5  to have a structured surface. Thus it can have a diffractive structure, a refractive structure (lenses) or macroscopic structures. It can further also have an unstructured, mirror-reflecting or scattering surface. 
     The optically variable element  0  thus has a partial thin film element which is formed by the only partially provided layers  3 ,  4  and  5  and/or a partial reflective layer  5 . Those partial elements enclose the surface region of a transparent window which is formed in the optically variable element  0  and in which the layers  3 ,  4  and  5  are absent. 
     It is possible in principle to forego one or more of the layers shown in  FIG. 1 . In addition the optically variable element  0  can also have one or more further layers. 
       FIGS. 2   a  through  2   c  show three optically variable elements  10 ,  20  and  30  respectively. The optically variable element  10  has three surface regions  11  through  13 , the optically variable element  20  has three surface regions  21  through  23  and the optically variable element  30  has three surface regions  31  through  33 . 
     The surface regions  12 ,  23  and  31  of the optically variable elements  10 ,  20  and  30  are each covered by a respective partial thin film element. As can be seen from  FIGS. 2   a  through  2   c , the partial thin film element is formed in each case in a region-wise and pattern-shaped manner. 
     It is possible in this case for the respective partial thin film element to be of a transmissive or reflective nature. A partial, pattern-shaped, both transmissive and also reflective configuration within the respective surface region makes it possible to achieve further attractive effects. In addition the surface regions  12 ,  23  and  31  can also be provided with a diffractive structure. 
     The surface regions  11 ,  22  and  33  of the optically variable elements  10 ,  20  and  30  respectively are each covered with a partial metallisation. Those surface regions can also be provided with a diffractive structure. 
     A respective transparent window is visible in each of the surface regions  13 ,  21  and  32  of the optically variable elements  10 ,  20  and  30 . The transparent windows each have a partial transparent element. That element has transparent or transmissive properties (clear lacquer compositions, oxidic, partially metallised, scattering, transmissive, organic and inorganic compositions). Those surface regions can also be provided with a diffractive structure. The transparent element can have diffractive structures, refractive structures (for example microlenses), macroscopic structures (larger than 5 μm) or a scattering surface. In that respect it is particularly advantageous, as already mentioned above, for that diffractive structure to extend into the adjoining surfaces regions  12 ,  22  and  31  and  33  respectively. In addition it is also possible for the transparent element to be colored. 
     It is possible that the transparent window is not enclosed by a single partial element, as shown in  FIGS. 2   a  and  2   b . Rather, it is also possible for two or more partial elements (partial reflective layer, partial thin film element) to jointly enclose the transparent window. Thus it is for example possible for the lower half of the surface  31  in  FIG. 2   c  to be formed by a partial thin film element and for the upper half of the surface  31  to be formed by a partial reflective layer. 
     It is to be emphasised that the diagrammatically illustrated element arrangements of  FIGS. 2   a  through  2   c  can all be embodied in register relationship with each other and without limitation in terms of generality, can embrace both graphic image elements, alphanumeric and geometric characters, bar codes and random patterns and combinations thereof. 
       FIG. 3  shows a possible way of constructing an optically variable element which is provided with a transparent window. 
       FIG. 3  shows a carrier  31 , five layers  32  through  37  and two surface regions  39   a  and  39   b.    
     The layer  32  is a protective lacquer and/or release layer, while the layer  33  is a replication layer formed for example by a replication lacquer. The layer  35  is a metal layer or an HRI layer (HRI=High Refraction Index). The layer  36  is formed by an etching resist. The layer  37  is an adhesive layer. 
     To produce the layer structure, the protective lacquer and release layer  32 , the replication layer  33  and the metal layer  35  are applied to the carrier  31  over the full surface area involved. Then the layer  35  is partially provided with diffractive structures by means of an embossing tool. The metal layer  35  is then printed upon with an etching resist, so that the only partially shaped layer  36  is formed. 
     The area which is not covered by the etching resist is then removed by etching. 
     Alternatively, it is also possible for the metal layer  5  to be demetallised or removed by ablation processes such as laser ablation, spark erosion, plasma or ion bombardment. It is possible by means of such ablation processes to transfer digitally stored images, texts and codes. 
     The intermediate spaces thus provided between the partial layers  35  and  36  form a transparent window. In addition a partial thin film element can be introduced into the intermediate spaces formed in that way between the partial layers  35  and  36  and covers only partial regions of the intermediate spaces. In this case, the layers of the partial thin film element can be applied by vapor deposition with suitably shaped vapor deposition masks or by printing on the layers, in the region of the intermediate spaces. 
       FIG. 4  shows an optically variable element in which the surface region of a transparent window has a spacer layer but not an absorption layer. 
       FIG. 4  shows a carrier  41 , five layers  42  through  47  and a plurality of surface regions  49   a  and  49   b.    
     The layer  42  is a protective lacquer and/or release layer, and the layer  43  is an absorption layer. The layer  44  is a spacer layer. The layer  46  is a metal layer or an HRI layer (HRI=High Refraction Index). The layer  47  is an adhesive layer. 
     To produce that layer structure, the protective lacquer and release layer  42  and the absorption layer  43  are applied to the carrier  41  over the full surface area involved. In this case the absorption layer  43  can be applied by vapor deposition or by a printing process. 
     The absorption layer is then partially removed in the surface regions  49   b.    
     That partial removal of the absorption layer is effected by positive etching or negative etching. Thus, in the case of direct etching, an etching agent can be applied in the form of a pattern by a printing process, for example by means of a roller or by screen printing. It is also possible to apply an etching mask which is removed by a washing operation after the etching process. 
     It is further possible for the absorption layer to be removed by an ablation process such as laser ablation, spark erosion, plasma or ion bombardment. By means of such ablation processes it is possible to transfer digitally stored images, texts and codes. 
     Instead of the absorption layer being applied over the full surface area, it is also possible for the absorption layer to be applied only partially to the layer  42 . That can be effected by vapor deposition by means of vapor deposition masks of a pattern configuration or by correspondingly pattern-shaped printing of the absorption layer  43  on the layer  42 . 
     The spacer layer  44  is now applied over the full surface area involved, to the partially shaped absorption layer  43 . The operation of applying the absorption layer can be effected for example by vapor deposition or by printing the absorption layer over the full surface area involved. 
     After that procedure the surface regions  49   a  are covered with a thin film comprising the absorption layer  43  and the spacer layer  44 . That thin film (after application of the further layers which act as optical separation layers) produces color shifts which are dependent on the viewing angle, by means of interference, upon suitable incidence of light. The absorption layer  43  is not present in the surface regions  49   b  so that such color shifts cannot be produced there. 
     It is further possible for not only the absorption layer  43  but also the spacer layer  44  to be only partially applied to the absorption layer  43  or partially removed. 
     There is on the one hand the possibility of applying the spacer layer  44  to the partially shaped absorption layer  43  over the full surface area involved and then removing the spacer layer by one of the above-described processes (positive etching, negative etching, ablation) in register relationship with the partially shaped absorption layer. 
     There is also the possibility of applying the absorption layer  43  and the spacer layer  44  over the full surface area and then removing both layers jointly by one of the above-described processes (positive etching, negative etching, ablation). 
     There is also the possibility of printing on the spacer layer in register relationship with the partially shaped absorption layer, by means of a printing process. 
     Alternatively it is also possible for the surface region of the transparent window to have an absorption layer but no spacer layer. 
     That can be achieved if the absorption layer is applied over the full surface area, for example by vapor deposition or printing. The spacer layer is then only partially applied by a printing process. Here too there is the possibility of the spacer layer being applied over the full surface area and then removed by one of the above-described processes (positive etching, negative etching, ablation). 
     There is also the possibility of the spacer layer or the absorption layer being altered in respect of its thickness by over-vapor deposition or over-printing, in such a way that it can no longer perform its function and is thus ‘extinguished’. 
     The layer  46  is now applied to the layers  43  and  44  which have been applied and configured in the above-indicated fashion. 
     If the layer  46  is a reflection layer it preferably comprises a metal. That metal can also be colored. The materials that can be used are essentially chromium, aluminum, copper, iron, nickel or an alloy with those materials. 
     It is further possible in that case to apply highly shiny or reflective metal pigments which then form the reflection layer. 
     The reflection layer  46  is in that case only partially applied so that the surface region of the transparent window is not covered by the reflection layer  46 . Here too there is the possibility that the layer  46  is first applied over the full surface area, for example by vapor deposition, and then removed by one of the above-described processes (positive etching, negative etching, ablation). Partial vapor deposition using a vapor deposition mask is also possible. If metal pigments are used as the reflective layer, that layer can be partially printed on, thereby then producing a partial reflective layer. 
     If the layer  46  is in the form of a transmission layer, in particular materials such as oxides, sulfides or chalcogenides can be used as materials for that layer. The crucial consideration in regard to the choice of the materials is that there is a difference in refractive index, in relation to the materials used in the spacer layer  44 . That difference should be not less than 0.2 to 0.5. Depending on the respective material used for the spacer layer  44 , an HRI material or an LRI material is thus used for the layer  46 . In this case the transmission layer can also be formed by an adhesive layer which satisfies that condition in regard to refractive index. 
     An ‘extinguishing effect’ as described hereinbefore can further be achieved by partial application of the transmission layer. If the spacer layer is adjoined by a layer (for example an adhesive layer) which does not satisfy the above-described condition in regard to refractive index, the optical thickness of the spacer layer is increased and the interference effect no longer occurs. 
     As shown in  FIG. 4  different partial elements occur due to that procedure in the surface regions  49   a  through  49   d:    
     The surface region  49   a  has a transmissive partial thin film element. The surface region  49   b  has a partial reflective element. The surface regions  49   c  have a reflective partial thin film element. The surface region  49   d  has a partial transparent element forming a transparent window. 
     Reference is now made to  FIGS. 5   a  and  5   b  to describe various further possible ways of producing and configuring a transparent partial layer in an optically variable element. 
       FIG. 5   a  shows a carrier  81 , seven layers  82  through  89  and a plurality of surface regions  89   a  and  89   b . The layer  82  is a protective lacquer and/or release layer. The layer  83  is a replication layer. It would also be possible in this case to forego that layer. The layer  84  is an absorption layer. The layer  84  forms a transparent element. The layer  88  is a metal layer. The layer  89  is an adhesive layer. 
     The layers  82 ,  83 ,  84 ,  85 ,  88  and  89  are of the configuration as described in the embodiments shown in  FIGS. 3 and 4  and are applied to the carrier  81  as described there. 
     The layer  86  is formed by a transmissive or transparent material. For example clear lacquer compositions but also oxidic, partially metallised, scattering, transmissive organic or inorganic compositions can be used as the material for the layer  86 . The layer  86  is applied to the layer  83  for example by a printing process. The processes described in the embodiments illustrated in  FIGS. 3 and 4  can also be used for applying the partial layer  86 . 
     The material used for the layer  86  can also be the same material as the material used for the spacer layer  85 . 
       FIG. 5   b  shows a carrier  91 , seven layers  92 ,  93 ,  94 ,  95 ,  96 ,  98  and  99 , diffractive structures  97  and a plurality of surface regions  99   a  through  99   d . The layer  92  is a protective lacquer and/or release layer. The layer  93  is a replication layer. The layer  94  is an absorption layer. The layer  96  forms the partial transparent element. The layer  98  is a metal layer. The layer  99  is an adhesive layer. 
     The layers  92 ,  93 ,  94 ,  95 ,  98  and  99 , are of the configuration as described in the embodiments shown in  FIGS. 3 and 4  and are applied to the carrier  91 , as described there. The layer  96  is of the configuration as stated in relation to  FIG. 5   a.    
     Prior to application of the layer  94  and/or the layer  96 , the diffractive structures  97  are applied to the surface of the layer  93  by means of an embossing tool or one of the other above-described processes. As can be seen from  FIG. 5   b , in this case the diffractive structures  97  can be applied both in surface regions which are covered by the partial transparent element and also can be applied to those surface regions which are not covered by the partial transparent element. 
       FIGS. 6 and 7  show some possible ways of combining a partial transparent element with partial diffractive structures, partial thin film elements and partial reflective layers, 
       FIG. 6  shows a carrier  101 , nine layers  102  through  109  and a plurality of surface regions  109   a  through  109   d . The layer  102  is a protective lacquer and/or release layer. The layer  103  is a replication layer. The layer  104  is an absorption layer. The layers  106  and  107   a  form a partial transparent element and the layers  106  and  107  form a partial reflective element. The layer  108  is a metal layer. The layer  109  is an adhesive layer. 
     The layers  102 ,  103 ,  104 ,  105 ,  108  and  109  are of the configuration as described with reference to  FIGS. 3 and 4  and are applied to the carrier  101  as described there. 
     The layer  107  is a metal layer which can be constructed as described in the embodiments shown in  FIG. 3 . The layers  106  and  107   a  are formed by a transmissive material. They are of the structure as described in the embodiments illustrated in  FIGS. 5   a  and  5   b.    
     As can be seen from  FIG. 6  a diffractive structure is further applied to the layer  103  in the surface regions  109   b ,  109   d  and  109   e.    
     Thus the optically variable element illustrated in  FIG. 6  has a partial transparent element in the surface region  109   d  and under some circumstances in the surface regions  109   a  (depending on the layer thickness of the layer  108 ). The optically variable element has a partial thin film element in the surface region  109   c . The optically variable element has a partial reflective element in the surface region  109   b  and  109   e.    
       FIG. 7  shows a carrier  111 , eight layers  112  through  119  and a plurality of surface regions  119   a  and  119   b . The layer  112  is a protective lacquer and/or release layer. The layer  113  is a replication layer. The layer  114  is an absorption layer. The layer  117  is a spacer layer. The layer  116  is an etching resist. The layers  115  and  118  are metal layers. The layer  119  is an adhesive layer. The layer  117  is a filling layer which can comprise the same material as the adhesive layer  119 . 
     The layers  112 ,  113 ,  114 ,  117 ,  118  and  119  are of the configuration as described in the embodiments shown in  FIGS. 3 and 4  and are applied to the carrier  111  as described there. 
     As can be seen from  FIG. 7  a diffractive structure  115   a  and  114   a  respectively is further applied to the layer  113  in the surface regions  119   c  and  119   d.    
     Thus the optically variable element shown in  FIG. 7  has a partial transparent element in the surface region  119   a . The optically variable element has a partial thin film element in the surface region  119   d . The optically variable element has a partial reflective layer in the surface regions  119   b  and  119   c.    
     The above-described possible processes make it possible to produce suitably adapted individual elements such as a partial transparent window, a partial thin film element, a partial structuring (for example diffractive structures) and a partial metallisation in a degree of positioning accuracy of ±0.2 mm in any positional combination in the form of a continuous or extensive image pattern.