EP3459758A1 - Valuable document, method for producing same and printer - Google Patents

Abstract

The invention relates to a method for producing a value document, in particular a banknote, comprising a) providing a value document substrate; b) printing the value document substrate with an ink based on magnetically orientable effect pigments or OVMI pigments; c) while the printed ink is still liquid, orienting or aligning the magnetically orientable effect pigments by means of a first magnetic field; d) the selective curing of the color matrix surrounding the magnetically oriented effect pigments by UV radiation or by laser radiation in a first region of the printed ink so that the effect pigments are immobilized in the aligned state, the curing having a resolution or a line width of less than 1 , 59 mm, preferably less than 800 microns, takes place.

Description

The invention relates to a method for producing a value document, in particular a banknote, and a document of value obtainable by the method. The invention further relates to a printing device suitable for carrying out the method.

Data carriers, such as valuables or identity documents, or other valuables, such as branded articles, are often provided with security elements for the purpose of security, which permit verification of the authenticity of the data carriers and at the same time serve as protection against unauthorized reproduction. Security elements with viewing-angle-dependent effects play a special role in the authentication of authenticity since they can not be reproduced even with the most modern copiers. The security elements are thereby equipped with optically variable elements that give the viewer a different image impression under different viewing angles and, for example, show a different color or brightness impression and / or another graphic motif depending on the viewing angle.

Security features for securing value documents, in particular banknotes, which contain magnetically orientable effect pigments are known in the prior art. Magnetically orientable effect pigments are commercially available, for example, under the trade name OVMI® from SICPA (the abbreviation OVMI stands for the term "optically variable magnetic ink"). The pigments typically have a platelet-like structure and are in the form of a layer composite, often comprising two layers of optical effect layers and one in between embedded magnetic layer includes. With regard to the optical effect layers, metallic-reflecting layers as well as color-shifting layer systems, eg with an absorber / dielectric / reflector structure, are suitable. The embedded magnetic layer is usually invisible, but is required to align the pigments.

The pigments dissolved in a printing ink are printed on a carrier substrate, for example banknote paper or a polymeric banknote substrate. Immediately after printing, the ink is still liquid, so that the platelet-shaped pigments within the color matrix surrounding the pigments are still freely movable. Subsequently, an external magnetic field is applied in which the pigments align themselves, the pigments typically being arranged parallel to the field lines due to the shape anisotropy. In this state, the color matrix surrounding the effect pigments is cured either by UV radiation or by the application of heat, so that the effect pigments are immobilized in the aligned state. For an observer arises in this way an optically variable effect, such as a light reflection that runs along the tilting direction when tilting the printing technology security element obtained. Depending on the applied magnetic field, various optically variable effects can be realized.

Based on the method described above, prior art magnetic ink areas can also be cured in two separate steps to realize more complex effects and / or image information. The FIG. 1 shows a paper substrate with a printable security feature based on OVMI pigments, with selective cure in two separate steps is carried out. In this case, the region (a) is selectively cured with a laser while applying a first magnetic field, while the remaining pigments in the region (b) remain freely movable. In this case, the selectively cured area can carry image information in the form of a border or projection. In the second step, the magnetic particle ink reaches a second magnet. The still freely moving particles in region (b) align themselves in the stray field of the second magnet and are subsequently cured by means of a UV flood exposure. According to the field lines of the first and the second magnet, the regions (a) and (b) now carry different orientations of the magnetic particles contained therein. This procedure is in the Scriptures EP 2 468 423 A1 described.

The EP 2 468 423 A1 describes the selective curing of a magnetic ink via the use of a laser or several lasers in the sense of an array, wherein the lasers are used either as focused or defocused point lasers or as line lasers. It describes resolutions ("projection of the laser beam") from 1.59mm to 9.5mm. Due to the very rough, minimal line width of 1.59 mm, there are inevitably disadvantages in terms of design choice. Thus, in the course of the laser treatment, only a very rough image information in the area (a) of FIG. 1 be introduced. Motives with fine weights can not be realized. Furthermore, the areas (a) and (b) of the FIG. 1 not nested effectively because this line widths of at most 200 microns, preferably less than 100 microns, more preferably less than 80 microns, are needed so that the individual lines are no longer visible to the human eye and the viewer gets the impression he sees a homogeneous picture. Accordingly, based on the state of the art so-called flip effects or overlapping pumping and running effects can not be realized.

Due to a finite number of laser sources, it is also not possible to cure large areas with different intensity distribution in a single-shot process. Line-based and / or point-based curing limits the process speed.

Based on the above-cited prior art, the object of the invention is to provide an improved production method for a security feature based on magnetically orientable effect pigments. In particular, finer resolutions should be achieved.

This object is achieved on the basis of the feature combination defined in the independent claim.

Further developments of the invention are the subject of the dependent claims.

Summary of the invention

• 1. (First aspect of the invention) A method for producing a value document, in particular a banknote, comprising
  1. a) providing a value document substrate;
  2. b) printing the value document substrate with an ink based on magnetically orientable effect pigments or OVMI pigments;
  3. c) while the printed ink is still liquid, orienting or aligning the magnetically orientable effect pigments by means of a first magnetic field;
  4. d) the selective curing of the magnetically oriented effect pigments surrounding color matrix by UV radiation or by laser radiation in a first region of the printed ink, so that the effect pigments are immobilized in the aligned state, wherein the curing with a resolution or a line width of less than 1.59 mm, preferably less than 800 microns, he follows.

The resolution or line width refers to the projected pixel size or line width of the light source at the location of the ink printed on the value document substrate and based on magnetically orientable effect pigments or OVMI pigments.

The term "selective curing" is to be understood as meaning that a specific or selected area of the printed ink is cured, in particular in order in this way to produce a region with information content and / or a particular optically variable effect.

The UV radiation is preferably a directed UV radiation.

The value document substrate provided in step a) is in particular a paper substrate, a plastic substrate, a film / paper / foil composite substrate (see, for example, US Pat WO 2006/066431 A1 ) or a paper / foil / paper composite substrate (see eg WO 2004/028825 A2 ).

• 2. (Bevorzugte Ausgestaltung) Verfahren nach Absatz 1, zusätzlich umfassend
  • e) den Schritt, in dem das erhaltene Wertdokumentsubstrat einem zweiten, vom ersten Magnetfeld abweichenden Magnetfeld ausgesetzt wird, um auf diese Weise noch nicht immobilisierte, magnetisch orientierbare Effektpigmente in einem bislang noch nicht bestrahlten, zweiten Bereich außerhalb des ersten Bereichs der aufgedruckten Druckfarbe zu orientieren bzw. auszurichten; und
  • f) das Aushärten der die magnetisch orientierten Effektpigmente umgebenden Farbmatrix im zweiten Bereich der aufgedruckten Druckfarbe durch Strahlung, insbesondere UV-Strahlung, sodass die Effektpigmente im ausgerichteten Zustand immobilisiert werden.
  Im Schritt f) kann das Bestrahlen, insbesondere mit UV-Licht, insbesondere vollflächig erfolgen.
  Insbesondere kann auf diese Weise ein mit magnetisch orientierbaren Effektpigmenten bedrucktes Wertdokumentsubstrat bereitgestellt werden, das in einem ersten Bereich der Druckschicht einen ersten optischen Effekt (bzw. ersten optisch variablen Effekt) aufweist und in einem zweiten Bereich der Druckschicht einen vom ersten optischen Effekt(bzw. ersten optisch variablen Effekt) abweichenden zweiten optischen Effekt (bzw. zweiten optisch variablen Effekt) aufweist.
• 3. (Bevorzugte Ausgestaltung) Verfahren nach Absatz 1 oder 2, wobei das selektive Aushärten im Schritt d) durch Verwenden einer Absorptionsmaske oder eines Mikrospiegelaktors (DMD) oder einer LCoS(Liquid Crystal on Silicon)-Technik oder einer LCD oder eines diffraktiven optischen Elements (DOE) oder eines Linsenarrays erfolgt.
• 4. (Bevorzugte Ausgestaltung) Verfahren nach einem der Absätze 1 bis 3, wobei das selektive Aushärten im Schritt d) in einem Single-Shot-Verfahren erfolgt.
  Im Single-Shot-Verfahren kann ein 2D-Array verwendet werden. Insbesondere wird hierbei ein 2D-DMD, eine LCoS(Liquid Crystal on Silicon)-Technik oder eine LCD verwendet.
• 5. (Bevorzugte Ausgestaltung) Verfahren nach einem der Absätze 1 bis 4, wobei das selektive Aushärten im Schritt d) ein linienbasiertes Härten ist.
  Beim linienbasierten Härten kann ein 1D-Array verwendet werden. Insbesondere wird hierbei ein 1D-DMD, eine LCoS(Liquid Crystal on Silicon)-Technik oder eine LCD verwendet.
• 6. (Bevorzugte Ausgestaltung) Verfahren nach einem der Absätze 1 bis 5, wobei das selektive Aushärten im Schritt d) mittels einer LCoS(Liquid Crystal on Silicon)-Technik erfolgt, insbesondere in Reflexion.
• 7. (Bevorzugte Ausgestaltung) Verfahren nach einem der Absätze 1 bis 5, wobei das selektive Aushärten im Schritt d) mittels einer LCD erfolgt.
• 8. (Bevorzugte Ausgestaltung) Verfahren nach einem der Absätze 1 bis 5, wobei das selektive Aushärten im Schritt d) durch Verwenden eines diffraktiven optischen Elements (DOE), insbesondere in Verbindung mit Laserstrahlung, erfolgt.
• 9. (Bevorzugte Ausgestaltung) Verfahren nach einem der Absätze 1 bis 5, wobei das selektive Aushärten im Schritt d) durch Verwenden eines Mikrolinsenarrays, insbesondere in Verbindung mit einer gerichteten UV-(Flut)Belichtung, erfolgt.
• 10. (Bevorzugte Ausgestaltung) Verfahren nach einem der Absätze 1 bis 9, wobei das selektive Aushärten der die magnetisch orientierten Effektpigmente umgebenden Farbmatrix im Schritt d), und gegebenenfalls im Schritt f), so erfolgt, dass die Effektpigmente im ausgerichteten Zustand immobilisiert werden und auf diese Weise einen optisch variablen Effekt erzeugen.
  Der optisch variable Effekt ist z.B. ein Lichtreflex, der beim Kippen des erhaltenen Wertdokuments entlang der Kipp-Richtung erfolgt.
  Im Falle, dass die Schritte e) und f) zwingend sind, können zwei Bereiche mit unterschiedlichen optisch variablen Effekten erhalten werden.
• 11. (Bevorzugte Ausgestaltung) Verfahren nach einem der Absätze 1 bis 10, wobei mittels des selektiven Aushärtens der die magnetisch orientierten Effektpigmente umgebenden Farbmatrix eine Bildinformation in Form von Zeichen oder einer Codierung, oder in Form eines Musters, einer Umrandung oder einer Projektion, erzeugt wird.
• 12. (Bevorzugte Ausgestaltung) Verfahren nach einem der Absätze 1 bis 11, wobei mittels des selektiven Aushärtens der die magnetisch orientierten Effektpigmente umgebenden Farbmatrix ineinander verschachtelte Bildbereiche erzeugt werden, die jeweils eine Auflösung bzw. eine Linienbreite von weniger als 200 µm, bevorzugt weniger als 100 µm und insbesondere bevorzugt weniger als 80 µm, aufweisen.
  Die Auflösung bzw. Linienbreite bezieht sich auf die projizierte Pixelgröße bzw. Linienbreite der Lichtquelle am Ort der auf das Wertdokumentsubstrat aufgedruckten, auf magnetisch orientierbaren Effektpigmenten bzw. OVMI-Pigmenten basierenden Druckfarbe.
• 13. (Zweiter Aspekt der Erfindung) Wertdokument, insbesondere eine Banknote, erhältlich durch das Verfahren nach einem der Absätze 1 bis 12.
  Das Wertdokument kann weiter im Besonderen eine Papierbanknote, Polymerbanknote oder Folienverbundbanknote, oder eine Ausweiskarte oder eine Passdatenseite sein.
• 14. (Dritter Aspekt der Erfindung) Druckvorrichtung zur Durchführung des Verfahrens nach einem der Absätze 1 bis 12, umfassend eine Einrichtung für das Bereitstellen eines Wertdokumentsubstrats, eine Einrichtung für das Bedrucken des Wertdokumentsubstrats mit einer auf magnetisch orientierbaren Effektpigmenten bzw. OVMI-Pigmenten basierenden Druckfarbe, einer Einrichtung für das Orientieren bzw. Ausrichten der magnetisch orientierbaren Effektpigmente mittels eines ersten Magnetfelds und einer Einrichtung für das selektive Aushärten der die magnetisch orientierten Effektpigmente umgebenden Farbmatrix durch UV-Strahlung oder durch Laserstrahlung in einem ersten Bereich der aufgedruckten Druckfarbe, sodass die Effektpigmente im ausgerichteten Zustand immobilisiert werden, wobei das Aushärten mit einer Auflösung bzw. einer Linienbreite von weniger als 1,59 mm, bevorzugt weniger als 800 µm, erfolgt.
• 15. (Bevorzugte Ausgestaltung) Druckvorrichtung nach Absatz 14, wobei die Einrichtung für das selektive Aushärten eine an die Durchführung der LCoS(Liquid Crystal on Silicon)-Technik angepasste Einrichtung ist oder die Einrichtung für das selektive Aushärten eine Absorptionsmaske oder einen Mikrospiegelaktor (DMD) oder eine LCD oder ein diffraktives optisches Element (DOE) oder einen Linsenarrays aufweist.
• 16. (Bevorzugte Ausgestaltung) Druckvorrichtung nach Absatz 14 oder 15, wobei die Druckvorrichtung weiterhin eine Einrichtung für das Erzeugen eines zweiten, vom ersten Magnetfeld abweichenden Magnetfelds aufweist, das dazu geeignet ist, noch nicht immobilisierte, magnetisch orientierbare Effektpigmente in einem bislang noch nicht bestrahlten, zweiten Bereich außerhalb des ersten Bereichs der aufgedruckten Druckfarbe zu orientieren bzw. auszurichten.
• 17. (Bevorzugte Ausgestaltung) Druckvorrichtung nach einem der Absätze 14 bis 16, wobei die Druckvorrichtung eine Siebdruckvorrichtung ist.

According to a variant, the value document substrate provided in step a) is a film substrate for producing security strips, security threads or security patches or security labels which are suitable for securing value documents, for example banknotes.

• 2. (Preferred embodiment) Method according to paragraph 1, additionally comprising
  • e) the step in which the resulting value document substrate is exposed to a second magnetic field deviating from the first magnetic field so as to orient non-immobilized, magnetically orientable effect pigments in a second region, which has not yet been irradiated, outside the first region of the printed ink or to align; and
  • f) the curing of the color matrix surrounding the magnetically oriented effect pigments in the second region of the printed ink by radiation, in particular UV radiation, so that the effect pigments are immobilized in the aligned state.
  In step f), irradiation, in particular with UV light, can take place in particular over the whole area.
  In particular, a value document substrate printed with magnetically orientable effect pigments can be provided in this way, which has a first optical effect (or first optically variable effect) in a first region of the printing layer and a first optical effect (or first optical effect) in a second region of the printing layer. first optically variable effect) deviating second optical effect (or second optically variable effect).
• 3. (Preferred Embodiment) Method according to paragraph 1 or 2, wherein the selective curing in step d) is accomplished by using an absorption mask or a micro-mirror actuator (DMD) or LCoS (Liquid Crystal on Silicon) technique or LCD or diffractive optical element (DOE) or a lens array.
• 4. (Preferred embodiment) The method according to any one of paragraphs 1 to 3, wherein the selective curing in step d) takes place in a single-shot method.
  In the single-shot method, a 2D array can be used. In particular, a 2D-DMD, an LCoS (Liquid Crystal on Silicon) technique or an LCD is used here.
• 5. (Preferred Embodiment) A method according to any one of paragraphs 1 to 4, wherein the selective cure in step d) is a line-based cure.
  For line-based curing, a 1D array can be used. In particular, a 1D DMD, an LCoS (Liquid Crystal on Silicon) technique or an LCD is used here.
• 6. (Preferred embodiment) Method according to one of paragraphs 1 to 5, wherein the selective curing in step d) takes place by means of an LCoS (Liquid Crystal on Silicon) technique, in particular in reflection.
• 7. (Preferred Embodiment) The method according to any one of paragraphs 1 to 5, wherein the selective curing in step d) is performed by means of an LCD.
• 8. (Preferred Embodiment) Method according to one of paragraphs 1 to 5, wherein the selective curing in step d) takes place by using a diffractive optical element (DOE), in particular in conjunction with laser radiation.
• 9. (Preferred Embodiment) A method according to any one of paragraphs 1 to 5, wherein the selective curing in step d) is performed by using a microlens array, in particular in conjunction with a directed UV (flood) exposure.
• 10. (Preferred embodiment) Method according to one of paragraphs 1 to 9, wherein the selective curing of the color matrix surrounding the magnetically oriented effect pigments in step d), and optionally in step f), takes place in such a way that the effect pigments are immobilized in the aligned state and create an optically variable effect in this way.
  The optically variable effect is, for example, a light reflection which takes place when tilting the resulting value document along the tilting direction.
  In the case where steps e) and f) are mandatory, two areas with different optically variable effects can be obtained.
• 11. (Preferred embodiment) Method according to one of paragraphs 1 to 10, wherein by means of the selective curing of the color matrix surrounding the magnetically oriented effect pigments generates image information in the form of characters or a coding, or in the form of a pattern, a border or a projection becomes.
• 12. (Preferred Embodiment) Method according to one of the paragraphs 1 to 11, wherein by means of the selective curing of the color matrix surrounding the magnetically oriented effect pigments, nested image areas are generated which each have a resolution or a resolution Line width of less than 200 microns, preferably less than 100 microns and more preferably less than 80 microns, have.
  The resolution or line width refers to the projected pixel size or line width of the light source at the location of the ink printed on the value document substrate and based on magnetically orientable effect pigments or OVMI pigments.
• 13. (Second aspect of the invention) Value document, in particular a banknote, obtainable by the method according to one of the paragraphs 1 to 12.
  The value document may further be in particular a paper banknote, polymer banknote or composite film banknote, or an identity card or a passport data page.
• 14. (Third aspect of the invention) A printing apparatus for performing the method according to any one of paragraphs 1 to 12, comprising means for providing a value document substrate, means for printing the value document substrate with an ink based on magnetically orientable effect pigments or OVMI pigments a device for orienting or aligning the magnetically orientable effect pigments by means of a first magnetic field and a device for the selective curing of the color matrix surrounding the magnetically oriented effect pigments by UV radiation or by laser radiation in a first region of the printed ink, so that the effect pigments in aligned state, wherein the curing with a resolution or a line width of less than 1.59 mm, preferably less than 800 microns, takes place.
• 15. (Preferred Embodiment) A printing device according to paragraph 14, wherein the selective curing device is a device adapted to perform the LCoS (Liquid Crystal on Silicon) technique, or the selective cure device is an absorption mask or micro-mirror actuator (DMD). or an LCD or a diffractive optical element (DOE) or a lens array.
• 16. (Preferred Embodiment) A printing apparatus according to paragraph 14 or 15, wherein the printing apparatus further comprises means for generating a second magnetic field deviating from the first magnetic field suitable for not yet immobilized magnetically orientable effect pigments in a hitherto unirradiated one to orient or align the second area outside the first area of the printed ink.
• 17. (Preferred Embodiment) A printing apparatus according to any one of paragraphs 14 to 16, wherein the printing apparatus is a screen printing apparatus.

Detailed Description of the Preferred Embodiments

In the present specification, instead of the phrase "magnetically orientable effect pigments", the abbreviation OVMI pigments is used.

• Option 1) Verwendung einer Absorptionsmaske.
• Option 2) Verwendung eines Mikrospiegelaktors (sogenannter "Digital Micromirror Device", hierfür wird nachstehend auch die Abkürzung DMD verwendet).

The invention relates to a method for partial or area hardening of magnetic ink, in which the intensity distribution of a strong UV lamp or a laser can be individually adjusted to the magnetic color in single-shot mode or in the To be able to cure mode of linear Abfahren and preferably to allow resolutions of less than 1.6mm. For selective hardening, for example, in the FIG. 1 In particular, the following methods 1) or 2) can be used:

• Option 1) Use of an absorption mask.
• Option 2) Use of a micro-mirror actuator (so-called "Digital Micromirror Device", for which the abbreviation DMD is used below).

• LCoS ("Liquid Crystal on Silicon", übersetzt ins Deutsche: Flüssigkristalle auf [einem] Silizium[substrat]) insbesondere in Reflexion;
• LCD bzw. eine Flüssigkristallanzeige, insbesondere in Transmission;
• DOE bzw. ein diffraktives optisches Element;
• ein Linsenarray.

The micromirror actuator is a microelectromechanical device for the dynamic modulation of light. In particular, a surface light modulator can be used. Here, the modulation of the light takes place via a mirror matrix. In particular, one of the following may be used:

• LCoS ("Liquid Crystal on Silicon", translated into German: liquid crystals on [a] silicon [substrate]), especially in reflection;
• LCD or a liquid crystal display, in particular in transmission;
• DOE or a diffractive optical element;
• a lens array.

The invention furthermore relates to a printing device for carrying out the production method according to the invention, comprising a device for providing a value document substrate, a device for printing the value document substrate with an ink based on magnetically orientable effect pigments or OVMI pigments, a device for orienting or Aligning the magnetically orientable effect pigments by means of a first magnetic field and means for selectively curing the color matrix surrounding the magnetically-oriented effect pigments by UV radiation or by laser radiation in a first region of the printed ink such that the effect pigments are immobilized in the aligned state, wherein the curing is at a resolution or linewidth, respectively less than 1.59 mm, preferably less than 800 μm.

It is preferred that the printing device has a selective cure device that is adapted to perform the liquid crystal on silicon (LCoS) technique, or the selective cure device comprises an absorption mask or a micro-mirror actuator (DMD) or a micromirror actuator (DMD) LCD or a diffractive optical element (DOE) or a lens array.

It is further preferred that the printing device additionally has a device for generating a second magnetic field deviating from the first magnetic field, which is suitable for non-immobilized, magnetically orientable effect pigments in a second region, which has not yet been irradiated, outside the first region of the printed image Orient or align printing ink.

The printing device is preferably a screen printing device or screen printing machine.

Further exemplary embodiments and advantages of the invention are explained below with reference to the figures, in the representation of which a representation true to scale and proportion has been dispensed with in order to increase the clarity.

Fig. 1

ein Wertdokumentsubstrat, z.B. ein Papiersubstrat zur Herstellung von Banknoten, das mit einer auf OVMI-Pigmenten basierenden Druckfarbe bedruckt ist, wobei das Aushärten der Druckschicht in zwei separaten Schritten erfolgt;

Fig. 2

die selektive Härtung einer Farbschicht mit OVMI-Pigmenten, wobei der Mikrospiegelaktor (DMD, 2D-Array) die eintreffende Strahlung reflektiert und eine frei wählbare Intensitätsmodulation auf der Substratebene erzeugt;

Fig. 3

eine linienbasierte, selektive Härtung einer Farbschicht mit OVMI-Pigmenten in Form eines Kreises mittels eines 1D-DMD Arrays, indem die Spiegel kontinuierlich ihre Steigung verändern, während das Substrat darunter durchfährt;

Fig. 4

die Beleuchtung eines 2D-DOE mit kohärenter Strahlung, um die Farbschicht mit OVMI-Pigmenten entsprechend dem Beugungsbild auszuhärten;

Fig. 5

ein DOE zur Erzeugung einer spezifischen Intensitätsmodulation zur Bildkodierung;

Fig. 6

ein Linsenarray in Kombination mit einer UV-Flutbelichtung zur schachbrettartigen Aushärtung einer Farbschicht mit OMVI-Pigmenten.

Show it:

Fig. 1

a value document substrate, eg a paper substrate for producing banknotes, which is printed with an ink based on OVMI pigments, the curing of the printing layer taking place in two separate steps;

Fig. 2

the selective curing of a color layer with OVMI pigments, wherein the micromirror actuator (DMD, 2D array) reflects the incident radiation and generates a freely selectable intensity modulation on the substrate plane;

Fig. 3

a line-based, selective hardening of a color layer with OVMI pigments in the form of a circle by means of a 1D-DMD array, in which the mirrors continuously change their pitch as the substrate passes underneath;

Fig. 4

illuminating a 2D DOE with coherent radiation to cure the color layer with OVMI pigments according to the diffraction pattern;

Fig. 5

a DOE for generating a specific intensity modulation for image coding;

Fig. 6

a lens array in combination with a UV flood exposure for the checkerboard curing of a color layer with OMVI pigments.

One embodiment is based on the use of an absorption mask.

The simplest way to form a light beam is based on the use of a mask which is opaque with respect to the wavelength used. In the case of UV light, this may e.g. a metallic grid or a metallic form, in particular based on aluminum, chromium, iron or the like. The mask is coated in a suitable material thickness, in particular greater than 200 nm, onto a transparent substrate, e.g. Glass, applied.

The disadvantage of using a mask, however, is the diffraction effect under laser irradiation, which results in masking of the mask in the OVMI plane.

Another embodiment is based on the use of a micromirror actuator or DMD.

Typical parameters are about 4 million pixels with a diagonal of 0.7 inches.

A micro-mirror actuator is based on a mirror array, ie a matrix-like arrangement of individual elements, wherein each individual element includes a tiltable reflecting surface with an edge length of a few micrometers. Each micromirror can be controlled flexibly by the force of electrostatic fields. The orientation of each mirror can be changed within a second up to 5000 times.

Depending on the orientation of the mirror array, light from a strong UV lamp or a laser can be deflected or reflected in such a way that an image (in the sense of an intensity modulation) is projected in the plane of the magnetic ink and selectively hardens in a pixel-selective manner. In order to focus, reduce or enlarge the projection image, projection lenses or other optical means can additionally be used.

For implementation, both a single-shot method with a 2D DMD, which images the entire image in the plane, as well as a line-based hardening with a 1D DMD possible, in which under continuous mirror change, the image is "written", while the substrate or OVMI paint passes under the DMD.

DMD and micromirror actuators ensure resolutions well below 1.6 mm and, with diameters of several centimeters, are larger than conventional OVMI-based, print-based security features. It would thus be conceivable to expose any OVMI pigment directly by means of a DMD without further optical means and thereby achieve line thicknesses in the micrometer range.

The FIG. 2 illustrates the selective curing of a color layer with OVMI pigments, wherein the micromirror actuator (DMD, 2D array) reflects the incident radiation and generates a freely selectable intensity modulation on the substrate plane. Illustrated is the single-shot method. Optionally existing optics between the micromirror actuator and the color layer with OVMI pigments is not shown.

The FIG. 3 Figure 1 illustrates a line-based, selective cure of a color layer with OVMI pigments in the form of a circle by means of a 1D DMD array, in which the mirrors continuously change their pitch as the substrate passes underneath.

Another embodiment is based on the use of an LCoS ("Liquid Crystal on Silicon", translated into German: liquid crystals on [a] silicon [substrate]), in particular in reflection.

Typical parameters are a chip size with a diagonal of 15.5 mm, an image size of 1920 x 1080 pixels, a reflectivity of 74% and a contrast ratio greater than 5000: 1.

In the same procedure, an LCoS can be used. This includes a silicon foil (acts as a reflector), a thin layer of liquid crystal based thereon, and a thin glass sheet. In contrast to the micromirrors of the DMD, in the case of the LCoS liquid crystal molecules are driven by an electrical voltage. The orientation of the latter determines whether or not light can successfully pass the polarizer again, i. whether light is reflected or absorbed by the LCoS. In contrast to the DMD, the LCoS requires polarized light and thus a higher output power of the light source. Again, a 1D design or a 2D design of the chip is possible.

Furthermore, an LCoS can be used not only in reflection but also in transmission.

Another embodiment is based on the use of an LCD or a liquid crystal display, in particular in transmission.

An LCD, in contrast to LCoS, has two polarizers and is transmitted in transmission, i. without reflection layer, operated. According to the orientation of the liquid crystal, it changes the polarization of the light and decides whether or not light can pass through the second polarizer.

LCD, LCoS and DMD are electronic "switchable" masks, so to speak.

Another embodiment is based on the use of a diffractive optical element (DOE).

Diffractive optical elements are glass substrates to which microstructures are applied by lithographic techniques. Through different optical path lengths (in particular by height variations or by refractive index variations) of the sub-beams, phase modulations occur in them, resulting in interference patterns which generate amplitude modulations by constructive and destructive superimposition. Thus, by skillful design, the intensity patterns of a laser beam - after transmission through the DOE - manipulate and the beam can be shaped accordingly. In this case, high-quality DOEs have high transmission values and efficiency values, i. they only slightly reduce the power of the input intensity.

1. a) Punktuelles, periodisches Beugungsmuster zur Verschachtelung eines Bereichs (a) und eines Bereichs (b) durch die Verwendung von 2D-Gittern (siehe Figur 4, die die Beleuchtung eines 2D-DOE mit kohärenter Strahlung zeigt, um die Farbschicht mit OVMI-Pigmenten entsprechend dem Beugungsbild auszuhärten).
2. b) Beugungsbilder individualisierter Form zur Aushärtung eines Bereichs (a) in entsprechender Form (siehe Figur 5, die ein DOE zur Erzeugung einer spezifischen Intensitätsmodulation zur Bildkodierung zeigt).
3. c) 1D-Gitter zur Erzeugung von Linienrastern. Das 1D-Gitter lässt sich z.B. so auslegen, dass das Beugungsbild einem Linienraster parallel zur Bahnrichtung bzw. Substratrichtung entspricht, was einen kontinuierlichen Aushärtungsprozess ermöglicht.

According to the design of the DOE many ways of curing can be realized:

1. a) Pointed, periodic diffraction pattern for interleaving a region (a) and a region (b) by the use of 2D gratings (please refer FIG. 4 showing the illumination of a 2D DOE with coherent radiation to cure the color layer with OVMI pigments according to the diffraction pattern).
2. b) Diffraction images of individualized form for curing a region (a) in appropriate form (see FIG. 5 showing a DOE for generating a specific intensity modulation for image coding).
3. c) 1D grid for generating line screens. The 1D grid can be designed, for example, so that the diffraction pattern corresponds to a line grid parallel to the web direction or substrate direction, which allows a continuous curing process.

Another embodiment is based on the use of a microlens array.

With the help of a microlens array, in combination with a directed UV flood exposure, a fast, large area and locally selective curing of the magnetic ink can be achieved. So, for example, Under normal incidence, each microlens illuminates the incident light at a point below the lens plane. With periodic arrangement of the lenses, a checkerboard-like curing of the magnetic ink could thus be realized. Furthermore, 1D lenticular screens (e.g., cylindrical lenses) can be used to create line-like cured areas that would allow for continuous illumination.

In general, variable grids can be produced when illuminating a lens array by varying the size and / or the spacings and / or the shape and / or the regularity of the individual lenses.

The FIG. 6 shows a lens array in combination with a UV flood exposure for the checkerboard curing of a color layer with OMVI pigments.

The method according to the invention offers numerous advantages over the prior art. In the prior art, various optical effects are known, which can be achieved by means of magnetic alignment of pigments and subsequent radiation curing. Also known is the possibility of combining several different effects by selective radiation curing. So far, however, only macroscopic surfaces (namely with a resolution greater than 1.6 mm) can be used for such combinations. In order to visualize different effects simultaneously and at the same location, however, many microscopic surfaces (in particular with a resolution of less than 200 μm) must be combined (or "nested") with one another, so that no disturbing rasters are visible. This is possible when using one or more of the techniques described herein. For example, flip effects can be realized where some effect is visible from one viewing angle area on the whole footprint of the security feature, and another effect is visible from another viewing angle area on the whole footprint of the security feature. Also, various motion effects can be seamlessly combined.

The nesting mechanism works as follows:

Below the resolution limit of the eye, a certain proportion of the OVMI area - in the form of a checkerboard pattern or line pattern - is given an effect (a).

This effect (a) is only at a viewing angle of e.g. 45 ° to see. The remaining free area is occupied with an effect (b) which is only at an angle of e.g. -45 ° can be seen. With the human eye, the rasterization or interleaving of the two effects is not recognizable. Now, for the viewer, the effect (a) appears over the entire surface at 45 ° and the effect (b) over the entire surface at below -45 °.

Claims (17)

Method for producing a value document, in particular a banknote, comprising a) providing a value document substrate; b) printing the value document substrate with an ink based on magnetically orientable effect pigments or OVMI pigments; c) while the printed ink is still liquid, orienting or aligning the magnetically orientable effect pigments by means of a first magnetic field; d) the selective curing of the color matrix surrounding the magnetically oriented effect pigments by UV radiation or by laser radiation in a first region of the printed ink so that the effect pigments are immobilized in the aligned state, the curing having a resolution or a line width of less than 1 , 59 mm, preferably less than 800 microns, takes place. The method of claim 1, additionally comprising e) the step in which the resulting value document substrate is exposed to a second magnetic field deviating from the first magnetic field so as to orient non-immobilized, magnetically orientable effect pigments in a second region, which has not yet been irradiated, outside the first region of the printed ink or to align; and f) the curing of the color matrix surrounding the magnetically oriented effect pigments in the second region of the printed ink by radiation, in particular UV radiation, so that the effect pigments are immobilized in the aligned state. The method of claim 1 or 2, wherein the selective curing in step d) by using an absorption mask or a micro-mirror actuator (DMD) or a LCoS (liquid crystal on silicon) technique or an LCD or a diffractive optical element (DOE) or a lens array he follows. Method according to one of claims 1 to 3, wherein the selective curing in step d) takes place in a single-shot method. The method of any one of claims 1 to 4, wherein the selective cure in step d) is a line-based cure. Method according to one of claims 1 to 5, wherein the selective curing in step d) by means of an LCoS (Liquid Crystal on Silicon) technique is carried out, in particular in reflection. Method according to one of claims 1 to 5, wherein the selective curing in step d) takes place by means of an LCD. Method according to one of claims 1 to 5, wherein the selective curing in step d) by using a diffractive optical element (DOE), in particular in conjunction with laser radiation occurs. Method according to one of claims 1 to 5, wherein the selective curing in step d) by using a microlens array, in particular in conjunction with a directed UV (flood) exposure, takes place. Method according to one of claims 1 to 9, wherein the selective curing of the color matrix surrounding the magnetically oriented effect pigments in step d), and optionally in step f), takes place in such a way that the effect pigments are immobilized in the aligned state and in this way an optically variable Create effect. Method according to one of claims 1 to 10, wherein by means of the selective curing of the color matrix surrounding the magnetically oriented effect pigments image information in the form of characters or a coding, or in the form of a pattern, a border or a projection, is generated. Method according to one of claims 1 to 11, wherein by means of the selective curing of the magnetically oriented effect pigments surrounding color matrix nested image areas are generated, each having a resolution or a line width of less than 200 microns, preferably less than 100 microns and more preferably less than 80 μm. Value document, in particular a banknote, obtainable by the method according to one of claims 1 to 12. Printing device for carrying out the method according to one of claims 1 to 12, comprising means for providing a value document substrate, means for printing the value document substrate with an ink based on magnetically orientable effect pigments or OVMI pigments, a device for orientation or Aligning the magnetically orientable effect pigments by means of a first magnetic field and a Device for selective curing of the color matrix surrounding the magnetically oriented effect pigments by UV radiation or by laser radiation in a first region of the printed ink, so that the effect pigments are immobilized in the aligned state, the curing with a resolution or a line width of less than 1 , 59 mm, preferably less than 800 microns, takes place. A printing apparatus according to claim 14, wherein the selective curing means is a liquid crystal on silicon (LCoS) adapted means or the selective curing means comprises an absorption mask or a micro-mirror actuator (DMD) or an LCD or a diffractive optical element (DOE) or a lens array. Printing device according to claim 14 or 15, wherein the printing device further comprises means for generating a second, deviating from the first magnetic field, which is suitable, not yet immobilized, magnetically orientable effect pigments in a previously not irradiated, second region outside the first Orient or align the area of the printed ink. A printing apparatus according to any one of claims 14 to 16, wherein the printing apparatus is a screen printing apparatus.

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