WO2019233625A1

WO2019233625A1 - Effect pigment, printing ink, security element, data carrier and production method

Info

Publication number: WO2019233625A1
Application number: PCT/EP2019/000172
Authority: WO
Inventors: Tobias Sattler; Jörg Anders; Maik Rudolf Johann Scherer; Kai Hermann SCHERER; Raphael DEHMEL; Christian Fuhse; Michael Rahm; Thomas Mang
Original assignee: Giesecke+Devrient Currency Technology Gmbh
Priority date: 2018-06-05
Filing date: 2019-05-28
Publication date: 2019-12-12
Also published as: DE102018004434A1; EP3802142A1

Abstract

The invention relates to a platelet-type magnetic effect pigment for use in printing ink, the effect pigment having a magnetic moment substantially perpendicular to the platelet plane.

Description

Effect pigment, printing ink, security element, data carrier and

production method

The invention relates to a platelet-shaped magnetic effect pigment for use in a printing ink, a printing ink, a security element for securing a value document or a valuable article, a data carrier, in particular a banknote, and methods for producing the effect pigment and the security element.

Data carriers, such as valuables or identity documents, or other items of value, such as branded articles, are often provided with security elements for securing purposes, which permit a 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 very latest copiers. The security elements are thereby equipped with optically variable elements which give the viewer a different image impression under different viewing angles and, for example, depending on the viewing angle, show a different color or brightness impression and / or another graphic motif.

Thin-film systems which produce a viewing angle-dependent color impression on the viewer by means of interference are known in the prior art. This optical effect can serve as an optically variable security element. A large-scale thin-film system can be comminuted by various techniques. The size of the resulting flakes or platelets can be laterally up to a few micrometers, but the size is usually in a range of 2gm to lOOmih. The vertical structure of a platelet is given by the requirements of the inter ference layers and is usually as thin as possible, eg in a range of 200 nm to 800 nm. Such platelets are used, for example, in optically variable color (so-called OVI® color), which serves to provide a security element.

Also known is the possibility of applying the color impression producing thin-film systems to a ferromagnetic material. Thus, the pigment platelets have a magnetic moment. Magnetically orienable effect pigments are e.g. commercially available 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 which often comprises two layers of optical effect layers With regard to the optical effect layers, metallic-reflecting layers as well as color-shifting layer systems, eg with an absorber, are used

Over / Dielektrikum / reflector structure, in question. The embedded magnetic layer is usually not visible, but is required to align the pigments.

In the prior art, it is also known to use such color pigments, which have a magnetic moment, for providing optically variable Si cherheitselemente. For this purpose, the pigments are introduced into a transparent binder. By means of an external magnetic field, the orientation of the pigments can be influenced immediately after printing on a printing material. Subsequently, the binder is cured, for example by means of UV irradiation, in order to fix the orientations of the pigments. By skillfully adjusting the spatial course of the Pigmentaus directions, it is possible to equip the printed substrate with optical motion effects. Since the magnetization direction of the pigments due If the shape anisotropy is preferably along the direction of the largest dimension of the pigments, the magnetic moment of the particles is aligned perpendicular to the normal vector of the thin layers. If a magnetic field with a field strength with the symbol "H" is applied, the pigments are oriented in such a way that their magnetic moments are as parallel as possible to the field vector (see attached FIG. 1).

As a consequence, the magnetic pigments can rotate about axes parallel to their magnetization with the symbol "m" arranged perpendicular to the normal vector of the thin films Pigments in one direction are substantially uniform while being essentially randomly distributed in another direction, thus not always showing a color surface of the pigment upwards (see attached Figure 2) .This leads to an expansion of the light reflection and to a reduced brilliance and sharpness of the optically variable effect.

The object of the present invention is to provide a method by which the control over the arrangement of the magnetic color pigments can be improved to allow a more attractive optical effect in this way.

This object is achieved on the basis of the feature combinations defined in the independent claims.

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

1. (First aspect of the invention) A platelet magnetic effect pigment for use in a printing ink, wherein the effect pigment has a magnetic moment substantially perpendicular to the platelet plane.

2. (Preferred Embodiment) Platelet-shaped magnetic effect pigment according to clause 1, wherein the effect pigment has a layer structure with a magnetic material arranged between two reflective layers

Layer has.

3. (Preferred embodiment) Platelet-shaped magnetic effect pigment according to Clause 2, wherein at least one reflective layer, preferably each of the two reflective layers, additionally with a translucent color layer or with an interference layer or with at least one further layer, which is used to produce a multilayer interference layer arrangement is combined. 4. (Preferred Embodiment) The platelet-shaped magnetic effect pigment according to any one of Clauses 2 or 3, wherein the magnetic layer is based on a ferromagnetic or ferrimagnetic material having a high coercive force. 5. (Preferred Embodiment) The platelet-shaped magnetic effect pigment according to any one of Clauses 2 to 4, wherein the magnetic layer is based on a rare earth metal and is preferably based on neodymium-iron-boron or samarium-cobalt. 6. (Preferred Embodiment) The platelet-shaped magnetic effect pigment according to any one of Clauses 2 to 4, wherein the magnetic layer is based on a Co / Cr alloy or on a layer structure based on the configuration NiFe / TiCr / CoCr-TaPt deposited on a Al / NiP substrate, based.

7. (Second aspect of the invention) Printing ink comprising platelet-shaped magnetic effect pigments according to any one of clauses 1 to 6.

8. (Preferred embodiment) Printing ink according to clause 7, wherein the printing ink comprises a binder, preferably a UV-curing binder or a thermosetting binder.

9. (Preferred embodiment) Printing ink according to clause 7 or 8, wherein the printing ink in addition to the platelet-shaped magnetic effect pigments according to any one of clauses 1 to 6 additionally conventional magnetic orien Tierierbare effect pigments, e.g. commercially available under the trade name OVMI®.

10. (Preferred embodiment) Security element for securing a value document or a valuable article, obtainable by printing technology applying the ink according to one of the clauses 7 to 9 on a substrate.

11. (Preferred embodiment) Security element according to clause 10, wherein the printing substrate is a value document substrate, preferably a paper substrate, a polymer substrate, a paper / polymer composite substrate or a paper-like substrate. 12. (Preferred embodiment) A security element according to clause 10 or 11, wherein for the viewer when viewing the security element, a viewing angle-dependent optical effect is perceptible based on the fixed in an external magnetic field and fixed in the cured binder pigments.

13. (Preferred embodiment) Security element according to one of the clauses 10 to 12, wherein the pigments along the security element in some areas in the form of patterns, characters or a coding before.

14. (Third aspect of the invention) Data carrier with a security element according to one of the clauses 10 to 13.

15. (Preferred embodiment) Data carrier according to clause 14, wherein the data carrier is a banknote or another document of value, a passport, a card, a payment card or an identity card.

16. (Fourth Aspect of the Invention) A method of producing the platelet-shaped magnetic effect pigment according to any one of Clauses 1 to 6, comprehensively

a) the step of producing a layer structure above a carrier substrate, the layer structure having a magnetic layer arranged between two reflective layers;

b) the step of detaching the layer structure from the carrier substrate;

optionally c) the step of crushing, e.g. by grinding until particles having an adequate size distribution are obtained;

optionally d) the step of mixing the resulting particles with a UV-curing or thermosetting binder to a (screen) printing ink. 17. (Fifth aspect of the invention) A method of manufacturing the security element according to any one of clauses 10 to 13, comprising printing by applying the ink according to any one of clauses 7 to 9 to a printing material, wherein in the step of printing applying the ink external magnetic field is applied and the color is cured, preferably by UV radiation or by heat, so that the particles become immobile.

Detailed Description of the Preferred Embodiments

The advantages of the invention will be explained below with reference to the schematically greatly simplified figures, in the representation of a scale and proportions true reproduction has been omitted in order to increase the vividness.

Show it:

FIG. 1 shows the possible magnetization (with the symbol "m") of an OVMI® pigment and the consequent orientation of the pigment in a magnetic field (with the symbol "H");

Figure 2 shows possible alignments of an OVMI® pigment in the magnetic field (with the symbol "H") by a rotation about an axis with the symbol "m"; and

FIG. 3 shows the rotation of the OVMI® pigment around the surface normal in the case of a magnetization that is parallel to the surface normal; At the same time, the intensity of the optical reflex does not change. The present invention is a printing technology available security element based on platelet-shaped magnetic Effektpigmen th whose magnetic moment is aligned substantially perpendicular to the platelet plane.

Similar to the magnetic pigments known in the prior art, the magnetic pigments according to the invention can be oriented in a static external magnetic field so that their magnetic moments are substantially parallel to the magnetic field lines. Just as with the known in the prior art magnetic pigments remains a degree of freedom: the platelets can rotate about an axis which is arranged parallel to its magneti's moment, without changing their potential energy in the magnetic field. In contrast to the known in the art Mag netpigmenten rotation in the case of the pigments of the invention, however, has no significant influence on the reflection properties of the Pig ments. The reflection properties can therefore be better controlled who the. In the case of the magnetic pigments known in the prior art, the viewer sees a large number of small pigments each having a substantially random brightness. Consequently, the security elements obtained in this way have a granular or a so-called "noisy" optical texture, whereas homogeneous pigments can be produced by means of the pigments according to the invention.

With regard to the preparation of the pigments according to the invention, there are various possibilities. All methods have in common that initially above a carrier substrate, for example a carrier foil, a layer structure is he testifies, wherein the layer structure has a arranged between two reflective layers magnetic layer. The reflective ones Layers can additionally be combined with translucent colors or with interference layers (or with further layers which lead to the generation of a multi-layer interference layer arrangement). Subsequently, the layer structure is detached from the carrier substrate and, if appropriate, comminuted, for example by means of grinding, until particles with an adequate size distribution are obtained. Thereafter, the resulting particles may be mixed with a UV-curing binder to form a screen printing ink. In the step of printing technical application of the ink on a substrate an external magnetic field is expediently applied and the color cured, for example, by UV radiation or by Wärmeein effect, so that the particles are immobile.

In the following, preferred methods for producing the magnetic layers in pigments of the invention are described.

First preferred production method:

It is a layer of ferromagnetic or ferrimagnetic Materi al, which has a high coercive force, applied to a carrier substrate. This layer is magnetized by means of an external magnetic field perpendicular to the layer plane. During magnetization it may be advantageous to increase the temperature of the layer for a short time, e.g. by means of IR radiation or by means of laser radiation), and / or to exert a high pressure on the material. In the further processing steps, the layers and / or pigments may only be exposed to external magnetic fields whose field strength is significantly lower than the coercive field strength of the magnetic layer.

Second preferred production method: A ferromagnetic or ferrimagnetic material having a very high coercive force is comminuted by grinding until a particle size of less than 10 mpi, preferably less than Impi, is obtained. The powder is introduced into a liquid medium which can be solidified in a controlled manner, and the mixture is applied to a carrier substrate.

The particles are then aligned by means of an external magnetic field so that their magnetization direction is arranged in each case perpendicular to the substrate plane, and the liquid medium is solidified, so that the particles are immobile and the magnetization of the layer is so to speak frozen. During the alignment by means of an external magnetic field, it may be advantageous to increase the temperature of the layer for a short time significantly and / or to exert a high pressure on the material. In the further processing steps, the layers and / or pigments may only be exposed to magnetic fields whose field strength is significantly lower than the coercive field strength of the magnetic layer.

Third preferred production method:

A magnetic layer is formed of such a material in which the shape anisotropy is not dominant and the magnetic moment is preferably perpendicular to the layer plane.

The above-described first preferred manufacturing method and the second preferred manufacturing method are each based on the prior art production of rare earth magnets, e.g. Neodymium iron boron or samarium cobalt.

The above-described third preferred manufacturing method is based on the well-known in the art manufacturing a hard disk or hard disk (ie, a magnetic storage medium of computer technology), in the Examples of materials which can be used are, inter alia, Co / Cr alloys or layer structures based on the configuration NiFe / TiCr / CoCr-TaPt deposited on an Al / NiP substrate. Substrate, for example, by sputtering.

The use of the particles according to the invention makes it possible to realize optically variable patterns, the surfaces produced in this way having an extremely homogeneous and brilliant effect compared to the patterns known in the prior art. In addition, novel patterns can be produced which can not be realized on the basis of the pigments known hitherto in the art, e.g. Micromirror bulging effects. Furthermore, the particles according to the invention can additionally be mixed with particles according to the prior art. When the resulting mixture is exposed to an external magnetic field, the principal planes of the two types of particles are locally perpendicular to each other, so that the pattern produced in this way is visible from widely different viewing angles. Thus, when tilting a security element produced in this way, firstly a viewing change between two different optically variable patterns can be visualized; secondly, the two particle types can have a different coloration, so that a color change can be made visible.

Claims

Patent claims

1. A platelet-shaped magnetic effect pigment for use in a printing ink, wherein the effect pigment has a magnetic moment oriented essentially perpendicular to the platelet plane.

2. The platelet-shaped magnetic effect pigment according to claim 1, wherein the effect pigment has a layer structure with a magnetic layer arranged between two reflecting layers.

3. The platelet-shaped magnetic effect pigment as claimed in claim 2, where at least one reflective layer, preferably each of the two reflective layers, is additionally combined with a translucent color layer or with an interference layer or with at least one further layer which leads to the production of a multilayer interference layer arrangement is.

4. The platelet-shaped magnetic effect pigment according to any one of claims 2 or 3, wherein the magnetic layer is based on a ferromagnetic or ferrimagnetic material having a high coercive force.

5. The platelet-shaped magnetic effect pigment according to any one of claims 2 to 4, wherein the magnetic layer is based on a rare earth metal and is preferably based on neodymium-iron-boron or samarium-cobalt.

6. platelet-shaped magnetic effect pigment according to any one of claims 2 to 4, wherein the magnetic layer on a Co / Cr Alloy or on a layer structure based on the configuration Ni-Fe / TiCr / CoCr-TaPt, deposited on an Al / NiP substrate based.

7. Printing ink, comprising platelet-shaped magnetic effect pigments according to one of claims 1 to 6.

8. Printing ink according to claim 7, wherein the printing ink comprises a binder, preferably a UV-curing binder or a thermosetting binder.

9. Printing ink according to claim 7 or 8, wherein the printing ink in addition to the platelet-shaped magnetic effect pigments according to any one of claims 1 to 6 additionally conventional magnetically orientable ef efektpigmente commercially available under the trade name OVMI® Lich, has.

10. Security element for securing a value document or a valuable article, obtainable by printing technology applying the ink according to one of claims 7 to 9 on a substrate.

11. The security element according to claim 10, wherein the printing substrate is a value document substrate, preferably a paper substrate, a polymer substrate, a paper / polymer composite substrate or a paper-like substrate.

12. A security element according to claim 10 or 11, wherein for the observer when viewing the security element, a viewing angle-dependent optical effect is perceptible, the on the in an exter- NEN magnetic field oriented and fixed in the cured binder pigments based.

13. A security element according to any one of claims 10 to 12, wherein the pigments along the security element area wise in the form of patterns, characters or a coding.

14. A data carrier with a security element according to one of claims 10 to 13.

15. A data carrier according to claim 14, wherein the data carrier is a banknote or another document of value, a passport, a document, a payment card or an identity card.

16. A method for producing the platelet-shaped magnetic effect pigment according to any one of claims 1 to 6, comprising

a) the step of generating a layer structure above a carrier substrate, wherein the layer structure comprises a magnetic layer arranged between two reflective layers;

b) the step of detaching the layer structure from the carrier substrate;

optionally c) the step of crushing, e.g. by grinding until particles with an adequate size distribution are obtained;

optionally d) the step of mixing the particles obtained with a UV-curing or thermosetting binder to a (screen printing ink.

17. A method for producing the security element according to any one of claims 10 to 13, comprising the printing technology applying the printing ink according to one of claims 7 to 9 on a substrate, wherein in Step of the printing technology applying the color of an external magnetic field is applied and the color is cured, preferably by UV radiation or by heat, so that the particles are immovable Lich.