Source: https://patents.google.com/patent/DE102007023560B4/en
Timestamp: 2020-01-22 09:36:35
Document Index: 375506879

Matched Legal Cases: ['art 511', 'art 512', 'art 601', 'art 602', 'art 611', 'art 612', 'arts 71']

DE102007023560B4 - Multi-layer body - Google Patents
DE102007023560B4
DE102007023560B4 DE102007023560A DE102007023560A DE102007023560B4 DE 102007023560 B4 DE102007023560 B4 DE 102007023560B4 DE 102007023560 A DE102007023560 A DE 102007023560A DE 102007023560 A DE102007023560 A DE 102007023560A DE 102007023560 B4 DE102007023560 B4 DE 102007023560B4
DE102007023560A
DE102007023560A1 (en
2007-05-21 Application filed by OVD Kinegram AG filed Critical OVD Kinegram AG
2007-05-21 Priority to DE102007023560A priority Critical patent/DE102007023560B4/en
2008-11-27 Publication of DE102007023560A1 publication Critical patent/DE102007023560A1/en
2009-02-05 Publication of DE102007023560B4 publication Critical patent/DE102007023560B4/en
2013-04-17 First worldwide family litigation filed litigation Critical https://patents.darts-ip.com/?family=39876988&utm_source=google_patent&utm_medium=platform_link&utm_campaign=public_patent_search&patent=DE102007023560(B4) "Global patent litigation dataset” by Darts-ip is licensed under a Creative Commons Attribution 4.0 International License.
The invention relates to a multilayer body (7) with a carrier substrate (750) and with a transparent layer (720) which is at least partially disposed in a window (70) or in a transparent region of the carrier substrate (750). The transparent layer (720) has at least one first (71a) and a second partial region (71b) with varying refractive index, which are arranged side by side in the layer plane spanned by the transparent layer (720) and at least partially in the window (70) or in the transparent region of the carrier substrate (750) are arranged. Each of the partial regions (71a, 71b) has a multiplicity of periodically arranged, optically acting element-forming, by refractive index variation formed nodes, which are arranged in substantially mutually parallel planes on. The planes in the at least first partial area (71a) are not parallel to the planes in the at least second partial area (71b). At least in one of the subregions (71a, 71b) the planes are neither parallel nor perpendicular to the layer plane. In this way, both the light incident on the front side and on the rear side of the multi-layer body (7) is diffracted by the optically active elements and the elements form a different visual effect in front and rear view.
The The invention relates to a multilayer body with optically acting Elements.
DE 43 34 847 A1 describes a document of value with a window-like, closed by a translucent film opening. The provided with a security feature, transparent film can thus be viewed not only in incident light, but also in transmitted light. In this case, the security feature may have a refractive and / or diffractive optically effective diffraction structure and / or thin-film arrangement.
Out WO 98/15418 A1 For example, a self-verifying security document is known which has a window closed with a transparent plastic material and a security element. The transparent plastic material has, in the region of the window, a verification means, for example an optical lens, a polarizing structure or an element for producing a moiré effect. To verify the security document, the security document is folded so that the window is aligned with the security element and the security element can be viewed through the window. The interaction of Verifizierungsmittel and security element results in a special visual effect.
In EP 0 435 029 B2 is a volume, eg. As a security or identification card, described with a liquid crystal security element, in which under the security element, a visually invisible coding is applied. The security element conveys different color impressions at different viewing angles. Such a liquid is also used in a product called varifeye ®. This product is a paper banknote into which a window is inserted, in a manner similar to a watermark. A transparent plastic film into which the liquid crystal and a diffractive OVD are introduced covers the window (OVD = optically variable device). Depending on the brightness of the background, the window will show different color effects. Optionally, in the window behind the liquid crystal, for example, a black print may be arranged so that a viewer perceives a color shift, even if the window is not viewed against a dark background.
DE 10 2006 016 139 A1 describes a method for producing a multilayer body having a volume hologram with at least two different image information. A photosensitive layer of the multilayer body is brought into contact with the front side of a master, directly or with the interposition of a transparent optical medium, into which interleaved areas having at least two different surface structures are formed which contain the at least two different image information. One of the surface structures has an asymmetric relief structure or a kinoform structure. The photosensitive layer and the master are exposed with a coherent light beam. The volume hologram thus introduced into the photosensitive layer is fixed by curing the photosensitive layer.
Of the Invention is the object of a multi-layer body with to provide an improved optically active element.
The The object of the invention is achieved through a multi-layered body, in particular a security document, with a carrier substrate and with a transparent layer at least partially in a window or in a transparent area of the carrier substrate is arranged, wherein the transparent layer at least one first and a second portion of varying refractive index having in the spanned by the transparent layer Layer layer are arranged side by side, wherein the at least first and the at least second subarea at least partially in the window or in the transparent area of the carrier substrate are arranged, each of the subregions a plurality of periodically arranged, forming an optically active element, by refractive index variation formed nodes, which in substantially parallel to each other Layers are arranged, and wherein the levels in the at least first subarea not parallel to the planes in the at least are second subarea, and wherein at least in one of the subregions the Planes are neither parallel nor perpendicular to the layer plane, so that both the front and the back the security element falling light through the optically acting Elements is diffracted and the elements in reflected light a in front view and in rear view different form optical effect.
The multilayer body according to the invention is characterized by special optical effects. The arrangement of the optically active elements in a window or in a transparent region of the carrier substrate makes it possible to illuminate the optically acting elements from both sides of the security document. In the following, a window is understood to mean a transparent area of the security document, which light can penetrate from both sides. Transparent means translucent, preferably transparent. This transparency can only be for one be be given limited spectral range, z. B. for red light. If the incidence of light on the side of the window, which faces a viewer, one speaks of reflected light. If light falls on the side of the window that faces away from the viewer, it is called transmitted light.
By an arrangement of at least two differently shaped Partitions in the window may be less transparent to achieve reflective images in a transparent window, the for the viewer particularly memorable is. Depending on the orientation of the levels in the at least two sub-areas, the angle of incidence of light on the multilayer body and the viewing angle of the multi-layer body arise different optical effects. A viewer takes in viewing the front of the multilayer body in incident light in the window, a first image information true. Becomes the security document by 180 degrees to a lying in the plane of the multilayer body Axis turned and the multi-layer body from the back Viewed, the viewer takes in reflected light in the window instead the first image information a different second Image information true. In a lying in the plane of the multilayer body Axis can be z. B. about an axis parallel to a longitudinal edge or act to a high edge of the multi-layer body. During a rotation of the multilayer body 180 degrees about a perpendicular to the plane of the multilayer body Axis other effects occur, for. B. a contrast dark / light / dark too dark / bright.
Of the inventive multilayer body records yourself as well characterized in that the described optically acting elements are formed in this way are that they divert incident light into narrow angle ranges or bow. These angular ranges are much narrower than typical ones diffractive structures, e.g. B. diffractive relief structures. Thereby a very selective optical effect is achieved, i. H. a viewer of the multilayer body decreases the optical effect only in a very limited, well-defined Angular range true.
Especially can be achieved with the multilayer body according to the invention be that image information contained in the optically acting element is included, only under very specific lighting situations becomes visible. For a viewer of the multi-layer body results when he the Multi-layer body tilts, thereby an unmistakable, sharp change between image information and missing image information.
Preferably If the multi-layer body is a security document. The multilayer body However, it can also be used in the decorative sector.
It can be provided that the optically acting elements in the transmitted light develop an optically variable effect. An optically active element can z. B. in the window or the transparent area of the carrier substrate be arranged that the optically active element in transmitted light can be considered. Preferably, the transparent layer shows of the multilayer body in Reflected light a different image information than viewed in transmitted light.
By the arrangement of at least two differently shaped Partitions in the window may be less transparent to achieve reflective images in a transparent window, the for the viewer particularly memorable is. Depending on the orientation of the levels in the at least two sub-areas, the angle of incidence of light on the multilayer body and The viewing angle of the multi-layer body is different optical effects. So it is z. B. possible for a viewer viewing the front of a security document in transmitted light in the window perceives a first image information. Will the security document otherwise unchanged Light incidence and viewing angle turned 180 degrees, so takes the viewer in transmitted light in the window instead of the first image information a second image information true.
In A preferred embodiment of the invention are the levels in opposite the first section tilted the levels in the second portion, preferably to an angle of at least 1 degree. This is the level of the Layer packages in the first section not parallel to the layers of the plane packet in the second subarea, and the intersection angle both level packages amounts at least 1 degree. It can be provided that the substantially mutually parallel planes in a first of the subregions contain a first image information that a viewer of the security document is visible by deflection or diffraction of light at the levels. It can further be provided that the substantially parallel to each other extending levels in a second of the subregions second image information contain a distraction to a viewer of the security document or diffraction of light at the levels is visible.
If now the planes in the first subarea are sufficiently different in their orientation from the orientation of the planes in the second subarea, a viewer takes in a first Lighting situation, the first image information and in a second lighting situation, the second image information true. An angle is understood to be sufficient here, preferably an angle greater than or equal to 1 degree at which the first and the second image information do not overlap and the observer perceives image information that is clearly separated from one another.
For example is a two-digit number, eg. As the number "50", by two different Subareas formed with different orientation of the planes, where the first digit is "5" as a subarea with a first orientation of the planes and the second digit "0" as a subregion is formed with a second orientation of the planes. To this Way is it z. Possible, that the first digit appears red and the second digit appears green.
Preferably Each of the subregions in the layer plane has an areal extent at least in each direction within the layer plane 20 microns. Preferably is this minimum surface area 300 μm. Through this area expansion becomes a subsection of the unarmed human eye always as coherent Entities perceived.
Further can be provided that each of the subregions an optically effective Having element generated as one by means of a special imaging technique Volume hologram is formed. Each of the volume holograms points formed by refractive index variation nodes. Ideally the knots are designed to form so-called Bragg planes, d. H. levels formed by refractive index variation. The refractive index changes are therefore localized in the Bragg planes, the first in connection with the X-ray structure analysis were described by crystals. The Bragg planes work In incident light as a diffraction grating and form by diffraction and interference an optical effect.
at In this embodiment, those in the subregions represent the refractive index variation formed nodes that are in the substantially parallel to each other extending levels are arranged, the Bragg levels of volume holograms dar. The substantially parallel planes in turn form the Bragg planes of volume holograms. The Alignment of the levels is done, for example, by using the below described special imaging technique as described above realized, so that the optically acting elements as special Volume hologram are realized.
Preferably stands out the transparent or semi-transparent layer, the in or on the security document according to the invention is arranged by optimally executed volume holograms, their thickness by the optical laws of the formation of volume holograms are limited to the bottom. The transparent layer can therefore also be used in a security document during the Use is claimed on bending, as for example in banknotes the case is. Because the volume hologram in a transparent layer is formed, is the unexpected visual effect of training nontransparent reflective images in a transparent Window particularly memorable.
in the Compared to conventional diffractive structures (rainbow holograms) is formed in the security document according to the invention Volume holograms make the contrast higher, and it is also possible in to save them phase information. This allows largely monochromatic, Bright pictures are produced only in a relatively narrow viewing angle be perceived.
It can be provided that the volume holograms in the transparent Layer can be generated by an optical contact copy of a master, in the interleaved areas with different ones asymmetric surface structures or Kinoform structures are formed, which are different Include image information. Through targeted choice of these structures the optically acting elements are formed so that in the at least two subregions specify the Bragg planes as above aligned and produce two different image information in reflected light, which are perceived from different viewing angles. It can also be provided by the targeted choice of these structures optically acting elements in such a way that the at least two Subareas in transmitted light two different image information generate that perceived at different viewing angles become.
Preferably the structures are chosen that the levels thereby formed in a first sub-area and the levels thereby formed in a second portion neither parallel nor perpendicular to the layer plane and that the planes in the first subarea are not parallel to the Layers are oriented in the second subarea.
In a preferred embodiment of the invention, the subregions are interleaved with each other. The interleaving is designed such that the first subregion consists of a multiplicity of first layers arranged next to one another in the layer plane Individual areas exists, the second subregion consists of a plurality of juxtaposed in the layer plane second individual areas, and the first and second individual areas are arranged in any arrangement in the layer plane side by side.
It is possible, that a first sub-area, consisting of a plurality of individual areas, a has first volume hologram with a first image information, and a second subarea consisting of a plurality of individual areas, has a second volume hologram with a second image information. By nesting the individual areas of the first subarea and the individual areas of the second subarea forms at a first Lighting situation the first part area a first volume holographic Image from, and in a second lighting situation, the second Subarea a second volume holographic image. For example recognizes a viewer of the security document in reflected light first, volume holographic image generated by the first subarea, and if he tilts the security document - a second, from the second Subarea generated, volume holographic image.
The Areas can be nested in different ways. It can For example, they are interlaced rasters, For example, line grid. In this case, the one area, for example a text information and the other area an image information. But it can also be provided that the one area information and the other area forms the environment of which the information takes off. The information may be, for example to act around a logo that looks bright in one viewing position a dark background appears and in the other viewing position dark against a light background. So it can be planned that when tilting or moving the volume hologram a change from a positive representation to a negative representation and vice versa. Next you can the areas are designed so that the one area is the edge of the other area forms. For example, the one area can be the border of an alphanumeric character and the other area the alphanumeric character itself.
In A preferred embodiment of the invention are the subregions with the at least two image information in a grid with a screen ruling smaller than 300 μm, preferably 20 microns up to 50 μm are arranged. Under particularly favorable conditions, d. H. when viewing contrasting subjects with good lighting is the limit of the resolution of the human eye at 300 microns. The resolution can at low contrast and unfavorable lighting around the Factors 3 to 5 worsen. Screen rulings from 20 μm to 50 μm can be used be unresolved by the unaided human eye, so that the screening of the image information is imperceptible and each visible region appears as a homogeneous region.
Further it can be provided that the grid is a strip grid is. A strip grid is particularly easy to implement. It can but other rasters may be provided, especially if more as two different image information nested inside each other should be. It can be, for example, a pixel grid act, wherein the master produced by electron beam technology is. The screening ensures that that the image information also in the volume hologram from each other are separated, so that brightness and / or sharpness losses due to superposition of image information in the volume hologram does not occur.
It is possible, too, that the optically-acting elements - rather than strictly from each other delimited interleaved areas, e.g. B. using Raster images - by related Areas are formed, for. B. using guilloches. Under a guilloche, an ornament of several into each other intricate and overlapping polylines understood, whereby the individual lines thereby string-like, often asymmetric, form closed ellipses or circular orbits. It is Z. B. possible, that a volume hologram is realized where the guilloche is for the viewer seems to turn when the transparent layer tipped back and forth becomes. This can be achieved by using every line of guilloche has a different azimuth. The master for generation of the guilloche hologram is designed as a blaze grid, each phase of the guilloche has a different azimuth between -45 and +45 degrees.
It may further be provided that the planes of the first portion with the layer plane include an angle between more than 45 degrees and less than 90 degrees. The planes of the first subregion are preferably arranged approximately perpendicular to the layer plane, in particular enclosing an angle of at least 80 degrees, but smaller than 90 degrees, with the layer plane. In this way, light that falls approximately perpendicular to the back of the security document is diffracted at the levels of the first sub-area through the window or the transparent area. The image information stored in the planes of the first subarea is thus perceived by a viewer in transmitted light. In addition, it can also be provided that the Ebe of the second portion with the layer plane include an angle of at most 30 degrees. In this case, the two subregions cooperate such that the planes of the first subregion form an optical effect in transmission (= in transmitted light), and the planes of the second subregion form an optical effect in reflection (= in reflected light).
Especially it can be provided that in the first subregion a transmission volume hologram is formed, whose Bragg's planes are approximately perpendicular to the layer plane stand. This will be on the back approximating the security element perpendicular to the layer plane incident through the transmission volume hologram passing light diffracted away from the normal of the layer plane. additionally it can be provided that in the second subregion a reflection volume hologram is formed, wherein the incident on the front of the security element Light is reflected.
For example contains the transmission volume hologram has first image information, e.g. As a square, and the reflection volume hologram a second Image information, e.g. For example, a star. If now the light on the front of the security document and this front page of the security document is considered the image information of the reflection volume hologram, d. H. the star, visible, noticeable. On the other hand, if the light on the back of the security document falls and the front side of the security document is illuminated the light through the window the transmission volume hologram, and the image information of the transmission volume hologram, i. H. the square becomes visible.
Preferably the transparent layer is formed as a photosensitive layer and preferably has a thickness of between 5 μm and 30 μm. The optimal strength of Transparent layer is among other things of the material used dependent and can be determined by experiment. Compared to diffractive Relief structures with a standard profile depth in the range of a few 100 nm, the transparent layer has a relatively large thickness on. The reason is that in a volume hologram the image information is stored in a volume and not - as in a diffractive relief structure - in a single interface (the diffractive surface relief).
In A preferred embodiment of the invention is the transparent Layer partially in an opaque region of the carrier substrate, preferably in a dark colored Area of the carrier substrate, arranged. It can be provided that the at least first and the at least second portion at least partially in the opaque Area of the carrier substrate are arranged. It can also be provided that both in the opaque area as well as in the transparent area of the security document in each case at least a first and an at least second subarea is arranged, wherein the image information in the respective first sub-areas is identical and the image information in the respective second sub-areas is identical. Preferably, in the first and second respectively Subareas arranged volume holograms.
The Volume hologram against the dark background is very visible. Due to the perceived color effect and brightness of the volume hologram the volume hologram can be a similar one Function as a well-known slide window, depending on the background a dark or a light surface shows, d. H. where the visible film area depending on the brightness changed becomes. Looking at the front of the security document, can a viewer behind the transparent area of the security document alternately arrange a dark and a light object. Depending on Brightness of the background changed the perceived color effect and brightness of the volume hologram. The volume hologram in the opaque area serves as a reference. If the background of the volume hologram is in the opaque area is dark, z. B. is printed with a dark color, takes the Viewer the volume hologram in the opaque area as colored and brighter true than that disposed in the transparent area Volume hologram.
It is possible, that the bottom of the transparent layer with dark ink is printed, z. B. the bottom of the transparent layer, in the volume holograms are arranged. Preferably, this is Print as a partial imprint with small printed areas in the window area and, for example, full-surface imprint in the opaque areas of the carrier substrate educated. It is also possible, that the transparent layer with a dark adhesive on the opaque areas of the carrier substrate is applied.
As a carrier substrate of the transparent layer, which is arranged in or on the security document according to the invention, z. B. a paper banknote with a window, a polymer banknote with a window or a polymer card with a window serve. An optical element formed by the transparent layer disposed in the multilayer body of the present invention may be disposed on or in a support substrate in one of the following manners. The optical element can be incorporated in a laminating film, which is shown as a strip or layer on a Pa pier banknote is arranged, wherein at least a part of the optical element is arranged in the region of a window of the banknote. Such a laminating film has, for example, in addition to the optical elements, a carrier film (for example PET film having a thickness of 12-60 μm) and an adhesive layer by means of which the laminating film is fixed on the banknote (PET = polyethylene terephthalate).
The optical element can also be in the transfer layer of a transfer film, in particular a hot stamping foil be introduced as a strip or patch on a paper banknote is applied, wherein at least a part of the optical element is arranged in the region of a window of the banknote. The optical Element can also, for. B. by means of hot stamping on the surface of a Polymer banknote. Furthermore, the optical Element also, z. B. by means of hot stamping the surface one of the plastic layers are applied, from which one Polymer banknote is composed, so that the optical element after the joining this plastic layers is embedded in the carrier substrate. The optical element may also be coated on the surface of a polymer card, e.g. B. an ID card attached (ID = Identification). In the event of an ID card with a PCI (= polycarbonate inlay), the optical element in or on attached to a layer that is considered one of the lower layers the finished card substrate is present; in other words, in the range of ID cards can be the optical element embedded in polycarbonate be.
Further can be provided that the transparent layer as part of a Foil structure is formed. The film structure has one or more elements from the following group: a diffractive OVD, preferably a diffractive relief structure, a color-shifting optical Element, a polarizing optical element, a diffractive or refractive lens, an array of diffractive or refractive microlenses, a color foil, an antenna for transmitting and / or receiving electromagnetic Signals, a solar cell, a display / display. It may be that arranged in the film structure elements the at least first and do not cover the second partitions, d. H. that the elements in the layer plane next to the at least first and second partial areas are arranged. It is also possible that arranged in the film structure elements the at least first and at least partially cover second portions, z. B. that a collaboration a lens and a volume hologram causes an additional visual effect.
In Another preferred embodiment is the transparent layer formed as part of a laminating film and / or transfer layer, the stripes or "patch" -shaped the carrier substrate is applied. Under a "patch" becomes a flat Foil or layer element with uniform or uneven outline understood, in which - im Contrary to a "strip" - the extension in the transverse direction does not differ significantly from the extent in the longitudinal direction.
In a further preferred embodiment, the transparent layer is formed as a photopolymer layer. Photopolymers are resins which crosslink by the action of high-energy light, in particular UV light, ie polymerize, and thereby change their refractive index (UV = ultraviolet). The transparent layer then forms a photosensitive layer, which is important for the production of the first and second partial areas with the image information contained therein. To produce volume holograms special photopolymers are provided whose refractive index changes by intensive exposure, such as OmniDex ® , produced by the company. DuPont.
in the The following is the invention with reference to several embodiments with the aid of the attached drawings by way of example. Show it:
1a , b a first application example of a security document according to the invention;
2a , b shows a second application example of a security document according to the invention;
3 a schematic representation of a volume hologram;
4a -D four possible arrangements of partial areas in a schematic representation in plan view;
5a a structure for producing a first transparent layer in a schematic sectional view;
5b the function of the first transparent layer in a schematic sectional view;
5c an arrangement example of the interleaved portions of the first transparent layer;
6a a structure for producing a second transparent layer in a schematic sectional view;
6b the function of the second transparent layer in a schematic sectional view;
6c an arrangement example of ver nested portions of the second transparent layer;
7a a schematic section through a third inventive security document;
7b a schematic representation of the function of in 7a illustrated security document when viewing the front;
7c a schematic representation of the function of in 7a illustrated security document when viewing the back;
8th a third example of application of a security document according to the invention;
9a , b schematic representations of the function of a security document according to the invention in reflected light and transmitted light.
The 1a and 1b show a security document 1 with a transparent layer 12 in the front view or in the rear view. The security document 1 is in the in 1a and 1b example illustrated a value document, such as a banknote or a check. Further, it is also possible that the security document 1 an identification document, for example a passport, forms. It is also possible that the security document 1 z. For example, a label for product security or a sticker on a transparent CD case for documentation of originality / authenticity is.
The security document 1 consists of a flexible carrier substrate 11 on which the transparent layer 12 in a window 15 is arranged. In the carrier substrate 11 it is preferably a carrier substrate made of paper material, which is provided with a print and in the other security features, such as watermarks or security threads are introduced. It can also be a non-flexible carrier substrate 11 be provided, as may be the case for example with ID cards or credit cards.
However, it is also possible that it is in the carrier substrate 11 is a plastic film or a laminate consisting of one or more paper and plastic layers.
The thickness of the carrier substrate is, if it is z. B. is a banknote, in a range between 0.06 mm and 0.15 mm. In the carrier substrate 11 is the window 15 , For example, by punching or cutting, introduced, which then by applying, for. B. full-surface sticking, the transparent layer 12 is closed again. This indicates the security document 1 a transparent layer 12 at least partially in the window 15 of the carrier substrate 11 is arranged.
However, it is also possible that as a material for the carrier substrate 11 already a transparent or partially transparent material is used and the carrier substrate thus in the region of the window 15 can remain. This is the case, for example, if the carrier substrate 11 has a transparent plastic film in the area of the window 15 is neither provided with a turbidity layer nor with pressure. Next, it is also possible the window 15 already in papermaking and the transparent layer 12 in the manner of a wide security thread in the carrier substrate 11 contribute.
Further it is also possible that the transparent layer or the film element only on the carrier substrate is applied and only then printed. Preferably, the transparent layer or the film element in this case from the back printed here.
It can in this case both "normal" printed materials used But are also provided with optically variable pigments printed materials be used.
During the manufacturing process of the security document 1 is it possible for the transparent layer 12 is applied to a bare, unprinted carrier substrate, for. B. after cutting the window 15 during manufacture of the carrier substrate. It is also possible that the transparent layer 12 is applied to an already finished printed carrier substrate, for. B. after an offset printing, but before a subsequent intaglio printing.
As in 1a and 1b is shown looking at the front of the security document 1 on the transparent layer 12 a maple leaf 13 to recognize. Looking at the back of the security document 1 is on the transparent layer 12 a cross 14 to recognize.
The 2a and 2 B now show a second example of application for the security document described above.
2a shows a security document 10 made of a flexible carrier substrate 101 consists, after the first manufacturing step, a window-shaped opening 104 having. In the illustrated example, the security document is 10 around a banknote. In a second manufacturing step was on the security document 10 a security strip 103 applied, the window-shaped opening 104 covered. The security strip 103 has two sections in the upper section 102 with varying refractive index, in the window-shaped opening 104 are arranged. The security strip 103 consists of a multi-layer body with a transparent layer 30 and a transparent carrier layer z. As polyethylene (= PE), polyethylene terephthalate (= PET), polyethylene naphthalate (= PEN) or polycarbonate (= PC) and has a thickness in the range of 5 to 20 microns.
The security strip 103 may be partially printed in offset, intaglio or screen printing, or placed on a substrate printed by one of these methods.
2 B shows a detailed view of the window-shaped opening 104 , The window-shaped opening 104 shows an outline in the form of a butterfly. The window-shaped opening 104 is with the security strip 103 covered, which is formed by a laminating film, which is a transparent layer 30 contains. The transparent layer 30 points in the area of the window-shaped opening 104 an indication of value 102 (the number "100"), as in the transparent layer 30 arranged volume hologram is formed. The remaining areas 105 the window-shaped opening 104 are designed as clear, transparent film areas. In 2 B is the review of the remaining areas 105 by showing one behind the security document 10 arranged text indicated.
3 shows a schematic vertical section through the transparent layer 30 , which is preferably a photopolymer layer having approximately plane-parallel surfaces 30a . 30b and a layer thickness 32 is. The layer thickness 32 typically ranges from 5 μm to 30 μm. Oblique to the through the layer 30 spanned, to both surfaces 30a . 30b the layer 30 approximately parallel layer plane 33 the layer 30 is indicated by a light-dark curve, a periodic modulation of the refractive index. Due to the refractive index variation is in the transparent layer 30 formed a plurality of periodically arranged nodes. These nodes, which in their entirety cause a diffraction of incident light and thus form an optically acting element, are in essentially mutually parallel planes 31 arranged. The nodes have a refractive index n 'which differs from a refractive index n of the residual regions of the transparent layer by the value δ: n' = n + B. The transparent layer 30 thus has a location-dependent refractive index n '= n + δ, whereby in the transparent layer 30 a three-dimensional refractive index pattern is stored.
This three-dimensional refractive index pattern can be generated by a holographic interference arrangement, e.g. Example, a structure in which a coherent light beam (a laser source) is deflected at a diffractive relief structure of a replicating: The for writing a volume hologram on the photopolymer layer 30 incident laser beam is first on the photopolymer layer 30 and then deflected at a reflection layer by diffraction at the lattice structure of the replication layer. The deflected beams represent an object wave which interferes with a reference wave represented by the incident beam and thereby in the photopolymer layer 30 triggers local polymerization. As a result of the polymerization, the refractive index of the photopolymer layer 30 changed locally. The refractive index changes are in the so-called Bragg planes 31 first described in conjunction with the X-ray crystal structure analysis.
Various Embodiments of such an arrangement will be described below.
to Production of a volume hologram, as in the security document according to the invention may be formed, is preferably the photosensitive layer directly or with the interposition of a transparent optical Media brought into contact with the front of a master, in the interleaved areas with at least two different ones surface structures are formed, which are the at least two different image information include. The surface structures are z. B. formed in the form of two asymmetric relief structures, by a particular embodiment for generating the above-described optical elements in the photosensitive layer (= transparent Layer) are suitable.
The asymmetrical relief structures are in this case designed such that they reflect or diffract the incident light in a predetermined angular position, which is determined so that the reflected / diffracted light beam occupies an angular position to the layer plane spanned by the transparent layer, which is perpendicular to the desired Orientation of the levels 31 stands. The angular position in which the two asymmetric relief structures reflect / diffract the incident light beam are, on the one hand, different and also depend on the angular position in which the coherent light beam is irradiated onto the asymmetrical relief structures. Starting from the desired orientation of the levels 31 As well as the construction of a predetermined holographic exposure arrangement, the deflection angle of the asymmetrical relief structures to be selected can thus be determined by simple calculation. Under distraction Here, the angle is to be understood by which the asymmetrical relief structure deflects a perpendicularly incident light beam by refractive reflection or diffraction from the surface normal. In this case, the blaze gratings explained below are preferably used as asymmetric relief structures. Furthermore, it is also possible to provide two different kinoforms in the corresponding surface area, which show a corresponding deflection behavior.
Of the Distortion angle of these asymmetric relief structures is preferably in a range between 10 ° and 30 °. The Photosensitive layer and the master are using a coherent light beam exposed and thus in the photosensitive layer introduced by interference resulting volume hologram is by curing the photosensitive layer fixed.
It can be provided that the photosensitive layer and the master through coherent, z. B. generated by a laser light rays different wavelength and / or different direction. To this It can be achieved that those stored in the volume hologram Image information in different colors appear and / or are visible from different angles.
It can be provided that the surface structures of the master partially contain no image information. The areas of the master, which contain no image information, z. B. as a background structure be used. Such background structures may e.g. B. be designed so that stray light and / or disturbing reflections be reduced. This can be achieved by making the areas of the master containing no image information as a moth-eye structure and / or designed as a mirror and / or as a matt structure and / or as a scatter grid are. It can too Antireflex structures or further optimized for this purpose Structures to be used.
In a further advantageous embodiment is provided that the at least two surface structures formed as mutually rotated asymmetric surface structures are. For example, a first asymmetric surface structure an approximate vertical flank and then a rising to the right Flank up. A second asymmetric surface structure has a similar structure except that the rising edge rises to the left, so relative to the first asymmetric surface structure turned 180 degrees.
The through these asymmetric surface structures after exposure have nodular Brechzahlinhomogenitäten introduced into the photosensitive layer in different, the different surface structures of the master corresponding sub-areas corresponding different orientations on. For example, in a first subarea, the levels are in oriented in a first direction and in the subsequent second Subarea oriented the planes in a second direction, the from the first direction by a rotation of 180 degrees.
A such orientation of the surface structures is particularly advantageous because the different image information by mere Tilting the security document are visible. The o. G. surface structures can also have an azimuthal variation, so that in The photosensitive layer produced optically active structures changing Create images when the photosensitive layer from left to right or vice versa is tilted.
advantageously, can be provided that it is the asymmetric surface structures around with a reflective surface provided Blazegitter with saw-toothed surfaces, For example, with a spatial frequency of 100 lines / mm to 150 Lines / mm.
Further can be provided that the Blazegitter a grid depth of 1 to 2 μm having. Blazegitter with the above dimensions can by thermoplastic deformation, for example by means of a heated Embossing roll, or photomechanically by exposing a UV-curable Lacks are generated. Generally it can be with the bars of the Masters around a mosaic-like Juxtaposition of a large Variety of different lattice act, z. For example, Blazegitter with a grating period of about 1000 nm and a grid depth between 100 and 500 nm with different azimuthal orientations, Kinoforms, asymmetric achromatic lattices, matt structures, Surface relief structures for the formation of freeform lenses, etc.
To reconstruct the into the photopolymer layer 30 stored volume hologram becomes the photopolymer layer 30 with white light 300 irradiated, as in 3 shown. This results in one direction 310 the approximate rendition of the volume hologram at a reconstruction wavelength used to write the volume hologram. The reconstruction wavelength can be selected by various methods, including: laser wavelength selection, lattice profile selection, and the choice of dyes in the photopolymer.
Further it is also possible that also the angle of incidence of the laser with respect to the grid of the master has an influence on the color reproduction determined by the embossing grid Has.
To shift the wavelength of the hologram, it is possible to shrink or grow the hologram before a barrier layer is deposited. This change in size of the hologram can be achieved, for example, by the action of heat or cold on the hologram before fixing, or by chemical means. Due to the manufacturing process, only relatively small deviations δ of the refractive index are possible. In order to achieve optical elements of high efficiency, is in the transparent layer 30 a high number of levels 31 with modulated refractive index and consequently a relatively large layer thickness 32 required. For such an arrangement of refractive index modulated planes 31 In the following, the term "Bragg grating" is used.
As already mentioned above, For example, the photopolymer layer may be the OmniDex photopolymer 706 of the company DuPont act, which is the said property of local refractive index change Exposure has. Photopolymers are also known which are known as liquid Substance present and polymerize, for example, by the action of UV light and thereby harden. It can also be provided to pour the photopolymer as a layer and precure by a weak UV light exposure and / or after training of the volume hologram due to UV light or by heat treatment cure.
4a to 4d shows four possible arrangements of above-described portions in window-like openings of a security document in a schematic representation in plan view. The illustrated arrangements each comprise two different Bragg gratings.
4a shows an arrangement with a horizontal extension 40a and a vertical extension 40b , Typically, the horizontal extent 40a a value of 20 mm and the vertical extent 40b a value of 15 mm. The arrangement includes regions having a first Bragg grating 41 , with a second Bragg grating 42 , and areas 43 without Bragg grating. In the standard situation, ie the usual viewing situation in reflected light from the front, the observer sees a bright red value, the number "806", caused by the areas with the first Bragg grating 41 , When the assembly is rotated 180 ° and viewed from the rear, the viewer perceives the outline of the value in green, as well as several small green maple leaves in the four corners, evoked by the areas with the second Bragg grating 42 , If one looks at the arrangement from the front and tilts the arrangement away from the standard situation, the bright green outline of the indication of value and the maple leaves appear.
4b shows a second arrangement comprising regions with a first Bragg grating 44 , with a second Bragg grating 45 , and areas 43 without Bragg grating. In the standard situation, ie, the usual viewing situation in reflected light from the front, the viewer sees a bright green maple leaf and two small green maple leaves, one in the upper left corner and, diagonally, in the lower right corner. If the arrangement is rotated by 180 ° and viewed from behind, the viewer perceives a bright green cross as well as a small green cross in the upper right corner and in the lower left corner. The central optical elements, the maple leaf and the cross, are formed as a nested strip grid. The juxtaposed strips are alternately assigned to one of the two optical motifs. The individual strips have a width of 100 μm. The repetition period of the strips, ie the distance between two strips assigned to the same motif (maple or cross), is therefore 200 μm. The ideal repetition periods, ie the ideal rest distances, depend on many factors, in particular the thickness of the photopolymer and the complexity of the representation. It is particularly advantageous in this case to keep the rest distances as small as possible, ie to choose so small that the maximum diffraction efficiency is still maintained.
considered one the arrangement from the front and tilt the arrangement from the standard situation away, so the bright green ones appear Cross and the two small green crosses, one each in the upper one right corner and in the lower left corner.
Typically, the strips of interlaced raster images have a width between 25 and 150 μm. Accordingly, the typical repetition period of the stripes, ie Distance between two stripes assigned to the same motif, between 50 and 300 μm.
4c shows a third arrangement comprising regions with a first Bragg grating 46 , with a second Bragg grating 47 , and areas 43 without Bragg grating. In the standard situation, ie, the usual viewing situation in reflected light from the front, the viewer sees a bright red maple leaf, with the left half of the sheet appearing as an area and the right half of the sheet as an outline. When the assembly is rotated by 180 ° around an axis lying in the plane of the page along the axis of symmetry of the maple leaf and viewed from behind, the viewer perceives a bright green cross, with the left half of the cross as an area and the right half as an outline. If one looks at the arrangement from the front and tilts the arrangement away from the standard situation, the bright green cross appears, with the right half of the cross appearing as an area and the left half of the cross as an outline.
4d shows a fourth arrangement comprising regions with a first Bragg grating 48 , with a second Bragg grating 49 , In the standard situation, ie, the usual viewing situation from the front, the viewer sees a bright green cross. If the arrangement is rotated by 180 ° and viewed from behind, the viewer perceives a red background cross. This effect can be designed similar to the diffractive watermark of KINEGRAM ®.
5a C represents the production of optical elements and their function when placed in front of an opaque surface. If a transparent layer as described above is arranged in front of an opaque substrate, during a reciprocation of the substrate a change between two different images typically results.
5a represents the production of an optical element. 5a shows a transparent carrier film 50 , which on its underside a transparent photopolymer layer 52 wearing. The transparent carrier foil 50 exists z. B. made of PET and has a thickness of 12 to 60 microns. The transparent photopolymer layer 52 exists z. B. from OmniDex ® 706 and has a thickness of 15 to 30 microns. The photopolymer layer 52 is preferably by printing or knife coating on the carrier film 50 applied.
Below the photopolymer layer 52 is a diffraction grating 53 arranged in the form of a surface relief. The diffraction grating 53 has areas with different relief structure, namely areas 53a with a first relief structure that deflects the incident light according to a first deflection angle, and areas 53b with a second relief structure that deflects the incident light according to one of different second deflection angles here. By deflection angle is here - as already defined above - understood the angle to the one perpendicular to the layer plane of the photopolymer layer 52 incident light beam is deflected by the corresponding relief structure by diffraction and / or reflection. In this case, this deflection angle is chosen as a function of the holographic exposure structure so that when exposed to the area 53a and 53b the levels 31 with the in 5a indicated different angular positions to each other and to that of the photopolymer layer 52 train layer planes (see also the above explanations). The areas 53a and 53b are hereby provided on the one hand alternately in the form of a strip grid. In the following are the areas 53a and 53b not provided over the entire area in the areas attributable to the strip grid, but provided only in regions according to a respective given image information. The areas 53a thus form an image information in the form of a number "810" in its extent, as also in FIG 5c is shown. The areas 53b thus form an image information in the form of a leaf in its extent, as also in 5c is shown.
The structures of the relief structure point in the plane of the diffraction grating 53 , ie in the horizontal direction typically dimensions in the range of 0.5 to 10 microns (= grid width), and in the vertical direction typically dimensions in the range of 50 nm to 10 microns (= lattice depth, structure depth) on.
To in the photopolymer layer 52 To achieve differently oriented optically effective levels, it can be provided that the dimensions of the relief structure change uniformly and / or that the tread depth and / or Spatialfrequenz continuously, z. B. linear, increase.
An approximately perpendicular to the carrier film 50 incident coherent light beam 500 , z. B. with a wavelength of 632.8 nm, passes through the carrier film 50 and the photopolymer layer 52 through and experiences at the diffraction grating 53 a diffraction-related distraction. One in the fields 53a Part deflected with the first relief structure 501 of the light beam interferes in the photopolymer layer 52 with the incident light beam 500 , One in the fields 53b Part deflected with the first relief structure 502 of the light beam also interferes in the photopolymer layer 52 with the incident light beam 500 , The way in the photopolymer layer 52 Bragg's planes introduced by two different volume holograms whose Bragg planes are like in 5a are indicated aligned in different angular position to each other, by curing the photopolymer layer 52 fixed, z. B. by the action of UV radiation. In the example shown, the photopolymer layer 52 two different, nested optical elements, one of which, in the areas 53a provided relief structures and the other of those in the areas 53b provided relief structures in the above-described imaging process is generated. Each optical element consists of the Bragg planes of a volume hologram, which are substantially parallel to each other in the in 5a indicated angular position are provided.
5b represents the function of in 5a described optical elements. 5b shows the transparent photopolymer layer 52 by means of an adhesive layer 57 on a carrier substrate 58 , z. B. a bill is attached. It is common that after curing of the photopolymer layer 52 a barrier layer on the lower surface of the photopolymer layer 52 is applied, with "lower surface" to the adhesive layer 57 directed surface of the photopolymer layer 52 means. This barrier layer prevents the diffusion of chemical substances that shrink or swell the Bragg grating of the photopolymer layer 52 could lead. The barrier layer is typically formed on the basis of a UV varnish. After the barrier layer has been applied, printing layers, adhesive layers for bonding to the carrier substrate, metal layers, etc. can be applied to the photopolymer layer 52 be applied.
The photopolymer layer 52 has the two nested optical elements, the first of which, in the first areas 52a arranged optical element in its surface area contains the number "810" as image information and the second, in second areas 52b arranged optical element in its surface area contains a sheet as image information. One from a light source 54 (Light bulb, fluorescent tube, sun, etc.) coming light beam 540 falls on the photopolymer layer 52 , is due to the diffraction structures of the photopolymer layer 52 distracted and leads to the reconstruction of the stored image information. A first deflected part 511 of the light beam 540 arrives in a first viewing position 55a into the eye of an observer, who perceives a volume-holographic image of the number "810." A second deflected part 512 of the light beam 540 arrives in a second viewing position 55b into the eye of the observer, who perceives a volume holographic image of the leaf. Usually it will be beneficial as an adhesive layer 57 to use a transparent adhesive, especially in the area of the window. However, it can also be a colored adhesive as an adhesive layer 57 be applied.
5c shows a view of the arrangement of the transparent photopolymer layer with the volume holographic image information against an opaque background 59 , The photopolymer layer has a stripe grid composed of the two interlaced image information. The grid lines are at a distance of approx. 50 μm from each other and are between 5 mm and 20 mm long. Depending on the viewing situation, ie depending on the incidence of light and viewing angle relative to the layer plane of the photopolymer layer, one or the other image information is visible. The wavelength of the light emanating from the respective optical element, ie the Bragg planes, depends on the structure of the optical elements, that is to say depends on the dimensions, in particular the spacing of the planes. At incidence of white light, z. Sunlight, a viewer perceives both volume holograms, both the number and the sheet, in a particular color, e.g. B. green. The change between the two image information results in the standard situation, ie in incident light when viewed from the front, when the photopolymer layer is tilted back and forth, regardless of whether the volume holograms are arranged in the region of a transparent window or over an opaque substrate.
6a -C represent the production of optical elements and their function when placed in front of an opaque surface. The fundamental difference to the in the 5c -C described elements is that it in the in the 6a -C described elements are not interleaved strip grid, but surface image information.
6a represents the production of an optical element. 6a shows a transparent carrier film 60 , which on its underside a transparent photopolymer layer 62 wearing. Below the photopolymer layer 62 is a diffraction grating 63 arranged in the form of a surface relief. The diffraction grating 63 has areas with different relief structure, namely areas 63a with a first, containing a sheet as image information relief structure and areas 63b with a second relief structure containing a cross as image information. In addition, there are still areas 63c in which the diffraction grating 63 has no lattice structures, z. B. is designed as a mirror. According to a further preferred embodiment are in the areas 63 Moth eye structures are provided which prevent reflection of the laser light in these areas and thus prevent the formation of Bragg lattice planes. The arrangement is made with light rays 600 illuminated by coherent light sources.
A red laser beam illuminates the grid area 63a , The red laser beam hits under one Angle of 10 degrees on the carrier film 60 on, passes through the carrier film 60 and the photopolymer layer 62 through and experiencing in the area 63a of the diffraction grating 63 a diffraction-related distraction. A deflected part 601 of the red laser beam interferes in the photopolymer layer 62 with the incident red laser beam. A green laser beam illuminates the grid area 63b , The green laser beam hits the carrier foil at an angle of -15 degrees 60 on, passes through the carrier film 60 and the photopolymer layer 62 through and experiencing in the area 63b of the diffraction grating 63 a diffraction-related distraction. A deflected part 602 of the green laser beam interferes in the photopolymer layer 62 with the incident green laser beam.
In this way, in the photopolymer layer 62 introduced Bragg planes of two different volume holograms are formed by curing the photopolymer layer 62 fixed. In the example shown, the photopolymer layer 62 two different, planar optical elements. Each optical element consists of the Bragg planes of a volume hologram. In that area 63c Bragg planes are not formed in any of the laser illuminations.
6b represents the function of in 6a described optical elements. 6b shows the transparent photopolymer layer 62 by means of an adhesive layer 67 on a carrier substrate 68 , z. B. a bill is attached. The angles of incidence of the laser beams 600 , the diffraction grating 63 with its two different areas 63a and 63b , the laser and the photopolymer layer 62 are selected so that in a first viewing situation (eg, depending on the tilt angle of the carrier substrate 68 ) in a first area 62a the photopolymer layer 62 a red "5" appears and in a second viewing situation (eg, depending on the tilt angle of the carrier substrate 68 ) in a second area 62b the photopolymer layer 62 a green "0" appears, one from a light source 54 (Light bulb, sun, etc.) coming light beam 540 falls on the photopolymer layer 62 , is due to the diffraction structures of the photopolymer layer 62 distracted and leads to the reconstruction of the stored image information. A first deflected part 611 of the light beam 540 arrives in a first viewing position 55a into the eye of an observer, who perceives a volume holographic image of the "5." A second deflected part 612 of the light beam 540 arrives in a second viewing position 55b into the eye of the observer, who perceives a volume holographic image of the "0".
6c shows a view of the arrangement of the transparent photopolymer layer with the volume holographic image information against an opaque background 69 , The photopolymer layer has juxtaposed planar optical elements, each of which has image information. Depending on the viewing situation, ie depending on the incidence of light and viewing angle relative to the layer plane of the photopolymer layer, one or the other image information is visible. For example, a viewer recognizes a "5" or a "0" if the carrier substrate is tilted to a different degree. The wavelength of the light emanating from the respective optical element, ie, the Bragg planes, depends on the structure of the optical elements, ie depends on the dimensions of the planes, etc. The background 69 stays always dark, because in this area no Bragg gratings were formed.
7a shows a section through a security document according to the invention 7 , The security document 7 is multi-layered and points, from the front of the security document 7 seen from behind, a laminate in a row 710 , a photopolymer layer 720 , an adhesive layer 730 and a banknote paper 750 on. In a subsection of the security document 7 is in the banknote paper 750 a window 70 recessed in another part is between the adhesive layer 730 and the banknote paper 750 a dark print layer 740 arranged. By backing with a dark, z. B. black, ink is an individualized optical effect achievable. For example, a banknote may be prior to the application of the photopolymer layer 720 printed with a black serial number on a light background.
In the photopolymer layer 720 are in the layer plane next to each other two identical optical elements 71 . 72 arranged, wherein the one element 71 in the area of the window 70 , the other element 72 in the area of the print layer 740 is arranged. Each of the optical elements 71 . 72 is through Bragg gratings one into the photopolymer layer 720 formed volume hologram formed. Each of the optical elements 71 . 72 has two parts 71a . 71b . 72a . 72b on. The subareas 71a and 72a have a Bragg grating with a first orientation of the Bragg planes and the subregions 71b and 72b have a Bragg grating with a second orientation of the Bragg planes.
7b shows that in 7a illustrated security document 7 in incident light in incident light 540a on the front of the security document 7 , The light beam in incident light 540a is through the Bragg grating of the subregions 71b and 72b in one direction 76 distracted. A viewer 55 in this direction 76 takes the through the Bragg grating of these subregions 71b and 72b true volume holograms formed, for example, a volume holographic image of a sheet. The light beam in incident light 540a is through the Bragg grating of the sections 71a and 72a in one direction 77 distracted. The viewer 55 takes the through the Bragg grating of these subregions 71a and 72a thus formed volume holograms not true.
7c shows that in 7a illustrated security document 7 after a rotation through 180 degrees, ie when light incident in reflected light 540a on the back of the security document 7 , The light beam in incident light 540a is through the Bragg grating of the subarea 71a in the direction 76 distracted. A viewer 55 in this direction 76 takes that through the Bragg grating of this subarea 71a Volume hologram formed true, for example, a volume holographic image of a cross. The light beam in incident light 540a is through the Bragg grating of the subarea 71b in the direction 77 distracted. The viewer 55 takes that through the Bragg grating of this subarea 71b thus formed volume hologram is not true. The second optical element 72 is covered by the carrier substrate and is illuminated from the back of the security document 7 without optical effect.
8th shows a security document 8th , which is a carrier substrate 80 and a security element 81 having. The security element 81 has a transparent layer, partially in the region of an opening 82 of the carrier substrate 80 is arranged, as well as an additional OVD 83 , At the OVD 83 it can be a diffractive OVD, z. B. a KINEGRAM ® , a color-shifting feature, eg. Example, an OVI (= Optically Variable Ink) or a liquid crystal, a polarizing element, diffractive or refractive lenses or microlens arrays, an antenna, a solar cell, a display device, or act on another electronic element. It can also be provided that a metal layer has been applied to the transparent layer in the region of the window, for. As aluminum, copper, silver or gold. Such a metal layer typically has a thickness in the range of 200 nm to 600 nm and may serve to generate reflections. The thickness of the metal layer may be selected such that it reflects in incident light and appears transparent in transmitted light.
This additional OVD 83 can serve as a reference for the effects of the transparent layer. For example, the in 8th illustrated OVD 83 to trade a KINEGRAM ® . A first volume hologram created by the transparent layer may be formed to appear bright just when it is in the OVD 83 included cross 830 bright appears. And a second volume hologram created by the transparent layer may be formed to appear bright just when one in the OVD 83 contained second picture appears bright.
9a and 9b show a section through a security document according to the invention 9 in reflected light and transmitted light. The security document 9 has a transparent layer, wherein in a first portion 91a the layer is a Bragg grating of a transmission volume hologram, e.g. B. with the image of a square, and in a second portion 91b the layer is a Bragg grating of a reflection volume hologram, e.g. B. with the image of a star is arranged. Both sections 91a and 91b are at least partially in the range of a window 90 of the security document 9 arranged so that the Bragg gratings in both reflected and transmitted light from a light source 54 can be illuminated. The Bragg gratings of the reflection volume hologram are oriented so that the Bragg planes occupy an angle of -30 to +30 degrees to the layer plane. The Bragg grating of the transmission volume hologram is oriented so that the Bragg planes are oriented approximately perpendicular to the layer plane of the transparent layer, preferably occupying an angle of -30 to +30 degrees to the layer plane normal.
9a shows the security document 9 in a reflected light arrangement. One from the light source 54 incoming light beam in incident light 540a falls at an acute angle to the front of the security document 9 , That in the subarea 91b arranged Bragg gratings of the reflection hologram directs a portion of the incident light in one direction 900 to a viewer 55 which perceives the image of the reflection volume hologram, ie the star.
9b shows the security document 9 in a transmitted light arrangement. One from the light source 54 incoming light beam in transmitted light 540d falls at an acute angle to the back of the security document 9 , That in the subarea 91a arranged Bragg gratings of the transmission hologram deflects a portion of the incident light in the direction 900 to the viewer 55 which perceives the image of the transmission volume hologram, ie the square.
Multilayer body ( 1 . 7 ), in particular a security document with a carrier substrate ( 11 . 58 . 750 ) and with a transparent layer ( 12 . 52 . 720 ), at least partially in a window ( 15 . 70 ) or in a transparent region of the carrier substrate ( 11 . 58 . 750 ), characterized in that the transparent layer ( 12 . 52 . 720 ) at least one first ( 52a . 71a ) and a second subregion ( 52b . 71b ) with varying refractive index, which is in the of the transparent layer ( 12 . 52 . 720 ) layer layer ( 33 ) by the side are arranged, wherein the at least first ( 52a . 71a ) and the at least second subarea ( 52b . 71b ) at least partially in the window ( 15 . 70 ) or in the transparent region of the carrier substrate ( 11 . 58 . 750 ) are arranged; that each of the subareas ( 52a . 52b . 71a . 71b ) a plurality of periodically arranged, an optically active element forming, by refractive index variation formed nodes, in substantially parallel planes ( 31 ) are arranged; and that the levels ( 31 ) in the at least first subarea ( 52a . 71a ) not parallel to the planes ( 31 ) in the at least second subarea ( 52b . 71b ) and that at least in one of the subareas ( 52a . 52b . 71a . 71b ) the levels ( 31 ) neither parallel nor perpendicular to the layer plane ( 33 ) so that both the front and the back of the multi-layer body ( 1 . 7 ) falling light ( 540 ) is diffracted by the optically acting elements and the elements in reflected light ( 540a ) form a different optical effect in front view and rear view.
Multilayer body ( 1 . 7 ) according to claim 1, characterized in that the planes ( 31 ) in the at least first subarea ( 52a . 71a ) with the layer plane ( 33 ) include an angle α with 45 ° <α <90 °, preferably almost perpendicular to the layer plane ( 33 ) are arranged so that the optically acting elements in the transmitted light ( 540d ) form a different optical effect in front view and rear view.
Multilayer body ( 1 . 7 ) according to claim 2, characterized in that the planes ( 31 ) in the at least second subarea ( 52b . 71b ) with the layer plane ( 33 ) include an angle of at most 30 degrees.
Multilayer body ( 1 . 7 ) according to one of the preceding claims, characterized in that the planes ( 31 ) in the at least first subarea ( 52a . 71a ) in relation to the levels ( 31 ) in the at least second subarea ( 52b . 71b ) are arranged so that the intersection angle of the planes ( 31 ) in the at least first subarea ( 52a . 71a ) with the levels ( 31 ) in the at least second subarea ( 52b . 71b ) is at least 1 degree.
Multilayer body ( 1 . 7 ) according to one of the preceding claims, characterized in that the smallest surface area of the subregions ( 52a . 52b . 71a . 71b ), in the layer plane ( 33 ), 300 microns, preferably 20 microns, is.
Multilayer body ( 1 . 7 ) according to one of the preceding claims, characterized in that the optically active element of the at least first subregion ( 52a . 71a ) and the optically active element of the at least second subregion ( 52b . 71b ) are formed as volume holograms, wherein the Bragg planes of each of the volume holograms are formed by the plurality of periodically arranged, forming an optically active element formed by refractive index variation node.
Multilayer body ( 1 . 7 ) according to one of the preceding claims, characterized in that the at least first and second subareas ( 52a . 52b . 71a . 71b ) are nested together so that the transparent layer ( 12 . 52 . 720 ) contains at least two different image information as a volume holographic image.
Multilayer body ( 1 . 7 ) according to claim 7, characterized in that the at least first and second subareas ( 52a . 52b . 71a . 71b ) are nested in the form of a line grid or area grid.
Multilayer body ( 1 . 7 ) according to one of claims 7 and 8, characterized in that the subregions ( 52a . 52b . 71a . 71b ) are arranged with the at least two image information in a grid with a grid size of less than 300 microns, preferably 50 microns.
Multilayer body ( 1 . 7 ) according to one of the preceding claims, characterized in that the transparent layer ( 12 . 52 . 720 ) a layer thickness ( 32 ) between 5 μm and 20 μm.
Multilayer body ( 1 . 7 ) according to one of the preceding claims, characterized in that the transparent layer ( 12 . 52 . 720 ) partially in an opaque, preferably dark colored area ( 740 ) of the carrier substrate ( 11 . 58 . 750 ) is arranged.
Multilayer body ( 1 . 7 ) according to one of the preceding claims, characterized in that the transparent layer ( 12 . 52 . 720 ) is formed as part of a film structure comprising one or more elements from the following group, wherein the one or more elements comprise the at least first and second subregions ( 52a . 52b . 71a . 71b ), or at least partially cover: a diffractive OVD, preferably a diffractive relief structure, a color-shifting optical element, a polarizing optical element, a diffractive or refractive lens, an array of diffractive or refractive microlenses, a color foil, an antenna, a solar cell, a display ,
Multilayer body ( 1 . 7 ) according to one of the preceding claims, characterized in that the transparent layer ( 12 . 52 . 720 ) as part of a laminating and / or transfer layer is formed, the strip or patch-shaped on the carrier substrate ( 11 . 58 . 750 ) is applied.
Multilayer body ( 1 . 7 ) according to one of the preceding claims, characterized in that the transparent layer ( 12 . 52 . 720 ) is formed as a photopolymer layer.
DE102007023560A 2007-05-21 2007-05-21 Multi-layer body Expired - Fee Related DE102007023560B4 (en)
US12/600,921 US8432589B2 (en) 2007-05-21 2008-05-16 Multi-layer body having optical-action elements for producing an optical effect
EP08758577.4A EP2155501B1 (en) 2007-05-21 2008-05-16 Multi-layer body
RU2009147278/12A RU2466874C2 (en) 2007-05-21 2008-05-16 Multilayer body
PL08758577T PL2155501T3 (en) 2007-05-21 2008-05-16 Multi-layer body
ES08758577T ES2436390T3 (en) 2007-05-21 2008-05-16 multilayer body
AU2008253266A AU2008253266B2 (en) 2007-05-21 2008-05-16 Multi-layer body
CA2687992A CA2687992C (en) 2007-05-21 2008-05-16 Multi-layer body
JP2010508726A JP5421246B2 (en) 2007-05-21 2008-05-16 Multilayer
CN2008800215970A CN101687426B (en) 2007-05-21 2008-05-16 Multi-layer body
BRPI0811931-7A BRPI0811931B1 (en) 2007-05-21 2008-05-16 Multiple layer body
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2019-11-19 R079 Amendment of ipc main class
Free format text: PREVIOUS MAIN CLASS: B42D0025300000