Security document and method for protecting a security document against forgery and for the authentication of the security document

Description

[0001] The present invention relates to a security document comprising a substrate and an optical security element incorporated in the substrate and relates to a method for checking the authentication of the security document Moreover, the invention relates to a method for protecting a security document against forgery and for the authentication of the security document

[0002] The identification and authentication of security documents, e.g. banknotes, credit cards, identity cards, tickets, stamps etc., is a long-standing problem. In order to solve this goal, security elements have been developed to allow users and/or machines to discriminate between genuine and forged security documents, in particular banknotes, and/or to discriminate among different types of banknotes.

[0003] Special substrates, special inks, the inclusion of watermarks and security threads are commonly used for protecting security documents, in particular banknotes, against forgery. Most of the security elements can be inspected with the naked eye. Another type of security elements are not visible with the naked eye, but can be inspected with a special device. Examples of such security elements are optical security elements based on fluorescent and polarisation effects.

[0004] WO 98/52077 describes an optical security element based on a layer structure consisting of an orientation layer and a layer consisting of liquid-crystal monomers cross-linked with one another. The orientation layer consists of a photo-arientable polymer network which is designated in literature as PPN or LPP layer. The PPN or LLP layer defines in the oriented state regions of altemating orientations. During production of the liquid-crystal layer structure, the liquid-crystal monomers are oriented through the interaction with the PNN layer in different zones. This orientation is fixed by a subsequent cross-linking step, after which a cross-linked, optical structured liquid-crystal (LCP) with a predetermined orientation pattern for storing information is formed. Under observation with the naked eye, the information which has been written in the LLP layer is not visible. Both layers have a transparent appearance. If the substrate on which the layers are located transmits light, then the stored Information becomes visible if the optical element is placed between two polariser sheets.

[0005] The above desctribed optical liquid-crystal structure allows storing any kind of information in form of text and/or images for providing optical security elements which can be incorporated in security documents. However, for checking the authentication of the security documents comprising the above optical security elements, polarisers are necessary to make visible the information stored therein.

[0006] When using an optical liquid-crystal structure as described in EP-A 689 084 and WO 9953349 A1, one polariser sheet is necessary on each side of the optical security element to read the stored information so that a quick checking of the authentication is difficult for the user (WO 98/52077). WO 98/52077 teaches removing this disadvantage by additionally integrating one polarising layer in the optical layer structure so that one polarising sheet held over the optical element is sufficient for making the stored information visible.

[0007] AU 2005 203 815 A1 discloses a security document having a plurality of PPN (photo-orientable polymer network) and LCP (liquid crystal polymer) layers. It also describes a polarizing layer which may be included in the security document. However, there is no disclosure regarding the arrangement of the LCP and PPN layers with respect to this polarizer. WO 2007/137334 A1 discloses a similar security document having a plurality of PPN layers (14, 24) and LCP layers (16, 26).

[0008] It is an object of the present invention to simplify the checking of the authentication of a security document, in particular a banknote, comprising an optical security element for storing information which is not visible with the naked eye. Another object ofthe invention is providing a method for protecting a security document, in particular a banknote, against forgery and for the authentication of the security document, which simplifies the checking of the authentication of the security document.

[0009] This problem is solved according to the invention with the features of the independent claims. Preferred embodiments are the subject-matter of the dependent claims.

[0010] The security document comprises a first liquid-crystal layer structure, a polariser, and a second liquid-aystal layer structure. The liquid-crystal molecules of the first layer structure have a first predetermined orientation pattern for storing information, while the liquid-crystal molecules of the second layer structure have a second predetermined orientation pattern for storing information. The information stored in the first and second liquid-crystal layer structures is not visible with the naked eye without an inspection tool.

[0011] Both the first information stored in the first liquid-crystal layer structure and the second information stored in the second liquid-crystal layer structure are independently visible for the public using an inspection tool. Thus, the optical security element allow authentication of the security document by observing both the first and second information which can be a text or an image or a combination of text and image.

[0012] The method for checking the authentication of the optical security element according to the invention is based on the use of a liquid-crystal display as a means for providing polarised light. Liquid-crystal displays emitting polarised light are well known. Since the screens of mobile telephones and cameras or other devices, e.g. a mobile TV, are liquid-crystal displays, mobile phones or cameras can be used by the public for making visible the stored information. Since the security document of the invention does not require a very special inspection tool, the inspection is simplified for the user.

[0013] The first information becomes visible when placing the optical security element of the security document on the liquid-crystal display in an orientation in which one of the sides of the optical security element is lying on the liquid-crystal display, while the second information becomes visible when placing the optical security element on the liquid-crystal display in an orientation in which the otherofthe sides of the optical security element is lying on the liquid-crystal display.

[0014] According to a preferred embodiment of the invention, the first predetermined orientation pattern is different from the second predetermined orientation pattern so that the first and second information distinguish from each other. However, it is basically possible to store the same information, e.g. text and/or image, in both liquid-crystal structures which can be inspected from both sides of the security document.

[0015] It is an important aspect of the invention that the substrate of the security document comprises a cutout and the optical security element is located in the cutout of the substrate. The optical security element can be placed on the upper or lower side of the substrate or can be incorporated in the substrate. Preferably, the optical security element is inserted into the substrate during the paper manufacturing process.

[0016] The above designated liquid-crystal layer structures as such are disclosed in e.g. EP-A 689 084, WO 9953349 A1 and WO 98/52077. Each of the first and second liquid layer structures comprises an anisotropic layer comprising cross-linked liquid-crystal monomers and an orientation layer arranged on the anisotropic layer of the first and second liquid-crystal layer structure, respectively, so that the liquid-crystal molecules of the liquid-crystal layer structures align with the information stored in the orientation layer. Both the orientation layers of the first and second liquid-crystal layer structures comprise a photo-oriented polymer network (PPN).

[0017] The optical security element of the invention is transparent under normal lighting conditions. The security element can be combined with other security features having surface grating effects, in particular with holograms, diffractive optical elements (DOE) zero order gratings etc. These security features can be incorporated in an additional layer in the polariser between the first and second liquid-crystal layer structures.

[0018] For the purpose of illustrating the present invention, a preferred embodiment of the invention will now be described below with reference to the accompanying drawings.

Fig. 1

shows a banknote comprising the optical security element of the security document according to the invention

Fig. 2

shows in a simplified schematic representation a layer structure of the optical security element of the security document according to the invention,

Fig. 3A

illustrates the inspection of the first information stored in the first optical security element of the security document according to the invention,

Fig. 3B

illustrates the inspection of the second information stored in the second optical security element and

Fig. 3C

illustrates the inspection of the optical security element under normal light conditions.

[0019] Fig. 1 shows the front side of a banknote comprising an optical security element according to the invention. The banknote comprises a substrate 1 made of a flexible material, e.g. the substrate is made of paper. A graphical design printing 2 is provided on the front side and the backside of the banknote. The banknote comprises conventional security elements, e.g. a security thread 3 made of a metal strip and a hologram 4.

[0020] The optical security element 5 of the banknote is a plastic band which has under normal lighting conditions a transparent appearance. The plastic band of the optical security element 5 is located in a cutout 6 of the substrate 1 of the banknote. Thus, under normal lighting conditions the optical security element appears as a window in the banknote. As will be described hereinafter, only under special lighting conditions, the information stored in the optical security element becomes visible for the public.

[0021] The plastic band of the optical security element is incorporated in the paper of the substrate during the paper manufacturing process. A method for incorporating a plastic band in the paper of a banknote is described for example in AT 412 078 B.

[0022] Fig. 2 shows in a simplified schematic representation the layer structure of the optical security element. The security element comprises a first liquid-crystal layer structure 7 and a second liquid-crystal layer structure 8 as well as polarizing sheet 9 arranged between the first and second liquid-crystal layer structures 7, 8.

[0023] The first liquid-crystal layer structure 7 comprises an anisotropic layer consisting of cross-linked liquid-crystal monomers 7A (LCP layer). The orientation of the molecular arrangement of the LCP layer is predetermined by the orientation of an orientation layer 7B which adjoins the LCP layer 7A. The orientation layer 7B is a photo-oriented polymer network (PPN) whose orientation varies locally over its surface. The orientation is determined by selective exposure to linearly polarized UV light. This liquid-crystal layer structure allows storing of information, i.e. a first image in the preferred embodiment. A method for producing the above liquid-crystal layer structure is described for example in EP-A 689 084, WO 9953349 A1, US-A 5 389 698, and WO 98/52077.

[0024] The second liquid-crystal layer structure 8 has the same structure as the first liquid-crystal layer structure 7. Both layer structures 7, 8 are hybrid structures consisting of cross-linked liquid-crystal monomers 7A, 8A (LCP layer) and a photo-oriented polymer network (PPN) 7B, 8B. In the preferred embodiment, the second liquid-crystal layer structure 8 stores a second image. In the preferred embodiment, the directions of orientation of the first and second liquid-crystal layer structures 7, 8 include a right angle.

[0025] Fig. 3A to 3C illustrate the inspection of the optical security element. In Fig. 3A to 3C, the first and second liquid-crystal layer structures 7, 8 (Fig. 2) showing the first and second images are designated with "1" and "2", respectively.

[0026] Under normal lighting conditions, the first and second images are not visible for the public when observing both the upper side and the lower side of the banknote (Fig. 3C) and the optical security element is transparent. Under special lighting conditions, however, both images become visible.

[0027] It is an important aspect of the invention that the user does not need a very special tool rather than the screen (LCD) of a mobile phone or a camera for making visible the images.

[0028] The second image becomes visible when placing the optical security element of the banknote with its lower side on the screen (LCD) and observing the upper side of the banknote with the naked eye (Fig. 3A). Accordingly, the first image becomes visible when placing the optical security element with its upper side on the screen (LCD) and observing the lower side of the banknote with the naked eye (Fig. 3B). The image is visible independent of the orientation of the optical security element on the screen. By rotating the security element on the screen, the image changes from positive to negative and vice versa.

Claims

1. A method of checking the authentication of a security document comprising a substrate (1) and an optical security element (5) incorporated in the substrate, characterized in that the optical security element (5) comprises:

a first liquid-crystal layer structure (7), the liquid-crystal molecules having a first predetermined orientation pattern for storing information,

a polarizer (9) and

a second liquid-crystal layer structure (8), the liquid-crystal molecules having a second predetermined orientation pattern for storing information the polarizer (9) being arranged between the first and second liquid-crystal layer structure (7, 8),

a cutout (6) in the substrate and the optical security element (5) being located in the cutout (6) of the substrate,
the method comprising the steps of:

providing a liquid-crystal display (LCD) for emitting polarized light placing the optical security element (5) of the security document on the liquid-crystal display (LCD) in an orientation in which one of the sides of the optical security element (5) is lying on the liquid-crystal display,

observing the optical security element (5) with the naked eye,

placing the optical security element (5) on the liquid-crystal display (LCD) in an orientation in which the other of the sides of the optical security element is (5) lying on the liquid-crystal display, and

observing the optical security element (5) with the naked eye.

2. The method according to claim 1 further comprising the steps of:

providing a mobile telephone or a camera comprising a liquid-crystal display for transmitting polarized light, the optical security element being placed on the liquid-crystal display of the mobile phone or camera.

3. The method according to claim 1 or 2, wherein the first predetermined orientation pattern of the first liquid-crystal layer structure (7) is different from the second predetermined orientation pattern of the second liquid-crystal layer structure (8).

4. The method according to claim 1 or 2, wherein the first liquid-crystal layer structure (7) and the second liquid-crystal layer structure (8) have different directions of orientation.

5. The method according to claim 4, wherein the directions of orientation of the first liquid-crystal layer structure (7) and the second liquid-crystal layer structure (8) include a right angle.

6. The method according to anyone of the preceding claims, wherein the first liquid-crystal layer structure (7) comprises an anisotropic layer (7A) comprising cross-linked liquid-crystal monomers and the second liquid-crystal layer structure (8) comprises an anisotropic layer (8A) comprising cross-linked liquid-crystal monomers.

7. The method according to anyone of the preceding claims, wherein the first liquid-crystal layer structure (7) comprises an orientation layer (7B) arranged on the anisotropic layer (7 A) of the first liquid-crystal layer structure and the second liquid-crystal layer structure (8) comprises a second orientation layer (8B) arranged on the anisotropic layer (8A) of the second liquid-crystal layer structure so that the liquid-crystal molecules of the first and second liquid-crystal layer structures (7, 8) align with the information stored in the orientation layer.

8. The method according to claim 7, characterized in that the orientation layer (7B) of the first liquid-crystal layer structure (7) comprises a photo-oriented polymer network (PPN) and the orientation layer (8B) of the second liquid-crystal layer structure (8) comprises a photo-oriented polymer network (PPN).

Ansprüche

1. Verfahren zur Überprüfung der Authentifizierung eines Sicherheitsdokuments mit einem Substrat (1) und einem optischen Sicherheitselement (5), das in das Substrat eingearbeitet ist, dadurch gekennzeichnet, dass das optische Sicherheitselement (5) Folgendes umfasst:

eine erste Flüssigkristallschichtstruktur (7), wobei die Flüssigkristallmoleküle ein erstes vorbestimmtes Ausrichtungsmuster zum Speichern von Informationen aufweisen,

einen Polarisator (9) und

eine zweite Flüssigkristallschichtstruktur (8), wobei die Flüssigkristallmoleküle ein zweites vorbestimmtes Ausrichtungsmuster zum Speichern von Informationen aufweisen,

wobei der Polarisator (9) zwischen der ersten und der zweiten Flüssigkristallschichtstruktur (7, 8) angeordnet ist,

einen Ausschnitt (6) in dem Substrat, und wobei sich das optische Sicherheitselement (5) in dem Ausschnitt (6) des Substrats befindet,
wobei das Verfahren die folgenden Schritte umfasst:

Bereitstellen einer Flüssigkristallanzeige (LCD) zum Abgeben von polarisiertem Licht,

Platzieren des optischen Sicherheitselements (5) des Sicherheitsdokuments auf der Flüssigkristallanzeige (LCD) in einer Ausrichtung, in der eine der Seiten des optischen Sicherheitselements (5) auf der Flüssigkristallanzeige liegt,

Betrachten des optischen Sicherheitselements (5) mit bloßem Auge,

Platzieren des optischen Sicherheitselements (5) auf der Flüssigkristallanzeige (LCD) in einer Ausrichtung, in der die andere der Seiten des optischen Sicherheitselements (5) auf der Flüssigkristallanzeige liegt, und

Betrachten des optischen Sicherheitselements (5) mit bloßem Auge.

2. Verfahren nach Anspruch 1, ferner mit den folgenden Schritten:

Bereitstellen eines Mobiltelefons oder einer Kamera mit einer Flüssigkristallanzeige zum Aussenden von polarisiertem Licht, wobei das optische Sicherheitselement auf die Flüssigkristallanzeige des Mobiltelefons oder der Kamera gelegt wird.

3. Verfahren nach Anspruch 1 oder 2, wobei das erste vorbestimmte Ausrichtungsmuster der ersten Flüssigkristallschichtstruktur (7) von dem zweiten vorbestimmten Ausrichtungsmuster der zweiten Flüssigkristallschichtstruktur (8) verschieden ist.

4. Verfahren nach Anspruch 1 oder 2, wobei die erste Flüssigkristallschichtstruktur (7) und die zweite Flüssigkristallschichtstruktur (8) unterschiedliche Ausrichtungsrichtungen aufweisen.

5. Verfahren nach Anspruch 4, wobei die Ausrichtungsrichtungen der ersten Flüssigkristallschichtstruktur (7) und der zweiten Flüssigkristallschichtstruktur (8) einen rechten Winkel einschließen.

6. Verfahren nach einem der vorhergehenden Ansprüche, wobei die erste Flüssigkristallschichtstruktur (7) eine anisotrope Schicht (7A) umfasst, die vernetzte Flüssigkristallmonomere umfasst, und die zweite Flüssigkristallschichtstruktur (8) eine anisotrope Schicht (8A) umfasst, die vernetzte Flüssigkristallmonomere umfasst.

7. Verfahren nach einem der vorhergehenden Ansprüche, wobei die erste Flüssigkristallschichtstruktur (7) eine Ausrichtungsschicht (7B) umfasst, die auf der anisotropen Schicht (7A) der ersten Flüssigkristallschichtstruktur angeordnet ist, und die zweite Flüssigkristallschichtstruktur (8) eine zweite Ausrichtungsschicht (8B) umfasst, die auf der anisotropen Schicht (8A) der zweiten Flüssigkristallschichtstruktur angeordnet ist, so dass die Flüssigkristallmoleküle der ersten und der zweiten Flüssigkristallschichtstruktur (7, 8) sich auf die in der Ausrichtungsschicht gespeicherten Informationen ausrichten.

8. Verfahren nach Anspruch 7, dadurch gekennzeichnet, dass die Ausrichtungsschicht (7B) der ersten Flüssigkristallschichtstruktur (7) ein photoorientiertes Polymernetzwerk (PPN) umfasst und die Ausrichtungsschicht (8B) der zweiten Flüssigkristallschichtstruktur (8) ein photoorientiertes Polymernetzwerk (PPN) umfasst.

Revendications

1. Procédé de vérification de l'authentification d'un document de sécurité présentant un substrat (1) et un élément de sécurité optique (5) incorporé dans le substrat, caractérisé en ce que l'élément de sécurité optique (5) présente :

une première structure de couche de cristaux liquides (7), les molécules de cristaux liquides présentant un premier motif d'orientation prédéterminé pour mémoriser des informations,

un polariseur (9), et

une deuxième structure de couche de cristaux liquides (8), les molécules de cristaux liquides présentant un deuxième motif d'orientation prédéterminé pour mémoriser des informations,

le polariseur (9) étant agencé entre la première et la deuxième structure de couche de cristaux liquides (7, 8),

une découpe (6) dans le substrat, et l'élément de sécurité optique (5) étant agencé dans la découpe (6) du substrat,

le procédé comprenant les étapes suivantes :

fournissement d'un écran à cristaux liquides (LCD) pour émettre de la lumière polarisée,

agencement de l'élément de sécurité optique (5) du document de sécurité sur l'écran à cristaux liquides (LCD) selon une orientation dans laquelle l'un des côtés de l'élément de sécurité optique (5) repose sur l'écran à cristaux liquides,

observation de l'élément de sécurité optique (5) à l'oeil nu,

agencement de l'élément de sécurité optique (5) sur l'écran à cristaux liquides (LCD) selon une orientation dans laquelle l'autre des côtés de l'élément de sécurité optique (5) repose sur l'écran à cristaux liquides, et

observation de l'élément de sécurité optique (5) à l'oeil nu.

2. Procédé selon la revendication 1, comprenant en outre les étapes suivantes :

fournissement d'un téléphone portable ou d'une caméra présentant un écran à cristaux liquides pour transmettre de la lumière polarisée, l'élément de sécurité optique étant placé sur l'écran à cristaux liquides du téléphone mobile ou de la caméra.

3. Procédé selon la revendication 1 ou 2, le premier motif d'orientation prédéterminé de la première structure de couche de cristaux liquides (7) étant différent du deuxième motif d'orientation prédéterminé de la deuxième structure de couche de cristaux liquides (8).

4. Procédé selon la revendication 1 ou 2, la première structure de couche de cristaux liquides (7) et la deuxième structure de couche de cristaux liquides (8) présentant différents sens d'orientation.

5. Procédé selon la revendication 4, les sens d'orientation de la première structure de couche de cristaux liquides (7) et de la deuxième structure de couche de cristaux liquides (8) incluant un angle droit.

6. Procédé selon l'une des revendications précédentes, la première structure de couche de cristaux liquides (7) comprenant une couche anisotrope (7A) qui comporte des monomères de cristaux liquides réticulés, et la deuxième structure de couche de cristaux liquides (8) comprenant une couche anisotrope (8A) comportant des monomères de cristaux liquides réticulés.

7. Procédé selon l'une des revendications précédentes, la première structure de couche de cristaux liquides (7) comprenant une couche d'orientation (7B) agencée sur la couche anisotrope (7A) de la première structure de couche de cristaux liquides, et la deuxième structure de couche de cristaux liquides (8) comprenant une deuxième couche d'orientation (8B) agencée sur la couche anisotrope (8A) de la deuxième structure de couche de cristaux liquides de sorte que les molécules de cristaux liquides de la première et de la deuxième structure de couche de cristaux liquides (7,8) s'alignent sur les informations mémorisées dans la couche d'orientation.

8. Procédé selon la revendication 7, caractérisé en ce que la couche d'orientation (7B) de la première structure de couche de cristaux liquides (7) comporte un réseau polymère photo-orienté (PPN) et la couche d'orientation (8B) de la deuxième structure de couche de cristaux liquides (8) comporte un réseau polymère photo-orienté (PPN).

Drawing