EFFECT PIGMENT, PRODUCTION METHOD, VALUE DOCUMENT AND PRINTING INK

Abstract

A platelet-shaped magnetic effect pigment is provided for use in a printing ink, and includes a layer construction with a magnetic layer and at least one optical functional layer, such that the magnetic layer is based on a magnetic material having a column-shaped nanostructure and the magnetic columns respectively have a largely uniform preferential magnetic direction deviating from the platelet plane.

Claims

1.-22. (canceled)

23. A platelet-shaped magnetic effect pigment for use in a printing ink, comprising a layer construction with a magnetic layer and at least one optical functional layer, wherein the magnetic layer is based on a magnetic material having a column-shaped nanostructure and the magnetic columns respectively have a largely uniform preferential magnetic direction deviating from the platelet plane.

24. The platelet-shaped magnetic effect pigment according to claim 23, wherein the largely uniform preferential magnetic direction of the magnetic columns is aligned substantially perpendicular to the platelet plane of the effect pigment.

25. The platelet-shaped magnetic effect pigment according to claim 23, wherein the largely uniform preferential magnetic direction of the magnetic columns is inclined towards the platelet plane and the angle of inclination, measured starting from the perpendicular to the platelet plane in a region of 1° to 20°.

26. The platelet-shaped magnetic effect pigment according to claim 23, wherein the magnetic columns respectively have a size of less than 1000 nm.

27. The platelet-shaped magnetic effect pigment according to claim 23, wherein the largely uniform preferential magnetic direction of the magnetic columns is a uniaxial magnetic anisotropy.

28. The platelet-shaped magnetic effect pigment according to claim 27, wherein the material of the magnetic layer is selected from the group consisting of BaFe12O19, FePt, CoCrPt, CoPt, BiMn, α-Fe2O3 and Nd2Fe14B and the largely uniform preferential magnetic direction of the magnetic columns is a uniaxial magnetic crystal anisotropy, or wherein the material of the magnetic layer is selected from the group consisting of iron, cobalt, nickel and an alloy of one or several of the aforementioned elements and the largely uniform preferential magnetic direction of the magnetic columns is a uniaxial magnetic shape anisotropy.

29. The platelet-shaped magnetic effect pigment according to claim 23, wherein the column-shaped nanostructure of the magnetic material is obtainable by means of the glancing angle deposition (GLAD) technique or the oblique angle deposition (OAD) technique.

30. The platelet-shaped magnetic effect pigment according to claim 23, wherein the optical functional layer is a metallic layer, a color layer obtainable by printing technology, an interference layer construction based on a reflective layer, a dielectric layer and an absorbent layer, or a combination of two or several of the aforementioned elements, including a color layer obtainable by printing technology and arranged above a metallic layer.

31. The platelet-shaped magnetic effect pigment according to claim 23, wherein the effect pigment has a sandwich-like layer construction and the magnetic layer as a central layer is provided both on the front side and on the back side with respectively one optical functional layer, wherein the two optical functional layers independently from each other are selected from a reflective metallic layer, a color layer obtainable by printing technology, an interference layer construction based on a reflective layer, a dielectric layer and an absorbent layer, or a combination of two or more of the aforementioned elements, including a color layer obtainable by printing technology and arranged above a reflective metallic layer.

32. The platelet-shaped magnetic effect pigment according to claim 31, wherein the effect pigment has an asymmetric layer construction with two optical functional layers differing from each other, which respectively are an interference layer construction based on a reflective layer, a dielectric layer and an absorbent layer and differ from each other with regard to the material or the layer thickness of the dielectric layer, and the effect pigment has the following layer sequence: absorbent layer-dielectric layer-reflective layer-magnetic layer-reflective layer-dielectric layer-absorbent layer.

33. The platelet-shaped magnetic effect pigment according to claim 31, wherein the effect pigment has a symmetric layer construction with two identical optical functional layers.

34. The platelet-shaped magnetic effect pigment according to claim 33, wherein the effect pigment has a symmetric layer construction, wherein the magnetic layer as a central layer is provided both on the front side and on the back side with respectively one optical functional layer, wherein the two optical functional layers respectively are an interference layer construction based on a reflective layer, a dielectric layer and an absorbent layer, and the effect pigment has the following layer sequence: absorbent layer-dielectric layer-reflective layer-magnetic layer-reflective layer-dielectric layer-absorbent layer.

35. The platelet-shaped magnetic effect pigment according to claim 30, wherein the optical functional layer is an interference layer construction based on a reflective layer, a dielectric layer and an absorbent layer and the effect pigment has the following layer sequence: absorbent layer-dielectric layer-reflective layer-dielectric layer-absorbent layer-magnetic layer.

36. The platelet-shaped magnetic effect pigment according to claim 32, wherein the effect pigment has an asymmetric layer construction, wherein the magnetic layer, on the front side, is provided with an interference layer construction based on a reflective layer, a dielectric layer and an absorbent layer and the magnetic layer, on the back side, is provided with a reflective metallic layer, so that the effect pigment has the following layer sequence: absorbent layer-dielectric layer-reflective layer-magnetic layer-reflective metallic layer.

37. A method for manufacturing a platelet-shaped magnetic effect pigment according to claim 23, comprising: a) producing a magnetic layer on the basis of a magnetic material having a column-shaped nanostructure, the magnetic columns being formed with a largely uniform preferential magnetic direction deviating from the plane of the magnetic layer; b) producing a layer construction having the magnetic layer and at least one optical functional layer; and c) crushing the layer construction obtained in step b) into individual platelet-shaped magnetic effect pigments.

38. A method for manufacturing a value document, comprising printing the value document substrate with a first printing ink containing platelet-shaped magnetic effect pigments according to claim 23 in a first region; aligning the platelet-shaped magnetic effect pigments in the first printing ink respectively printed in the first region by means of an external magnetic field; curing the first printing ink printed in the first region.

39. The method according to claim 38, comprising: printing the value document substrate with a first printing ink containing first platelet-shaped magnetic effect pigments in a first region; printing the value document substrate with a second printing ink containing second platelet-shaped magnetic effect pigments in a second region adjacent to the first region, the second effect pigments being visually different from the first effect pigments; aligning the platelet-shaped magnetic effect pigments in the first and/or the second printing ink printed in the first region and in the second region, respectively, by means of an external magnetic field; curing the first and/or the second printing ink printed in the first region and in the second region, respectively.

40. The method according to claim 38, comprising: printing the value document substrate with a first printing ink containing platelet-shaped magnetic effect pigments in a first region; printing the value document substrate with a second printing ink containing conventional platelet-shaped magnetic effect pigments in a second region adjacent to the first region, the conventional platelet-shaped magnetic effect pigments having a preferential magnetic direction extending along the platelet plane; aligning the platelet-shaped magnetic effect pigments in the first and/or the second printing ink printed in the first region and in the second region, respectively, by means of an external magnetic field; curing the first and/or the second printing ink printed in the first region and in the second region, respectively, so that the two regions have a clearly distinguishable appearance due to the different alignment of the two types of effect pigments.

41. A value document obtainable by the method according to claim 38.

42. The value document according to claim 41, wherein the value document is a bank note or an identification document.

43. A printing ink comprising platelet-shaped magnetic effect pigments according to claim 23.

44. The printing ink according to claim 43, wherein the printing ink comprises a binding agent including a UV-curing binding agent, a binding agent curing by means of electron beams or a heat-curing binding agent.

Description

[0074] There are shown:

[0075] FIG. 1 a column-shaped nanostructure made of magnetic material produced above a substrate by means of glancing angle deposition (GLAD), with the columns being oriented perpendicular to the substrate plane;

[0076] FIG. 2 a column-shaped nanostructure made of magnetic material produced above a substrate by means of glancing angle deposition (GLAD), with the columns being inclined towards to the substrate plane;

[0077] FIG. 3 an example of a magnetic layer of an effect pigment according to the invention;

[0078] FIG. 4 an example of a layer construction (detail) starting from which platelet-shaped magnetic effect pigments according to the invention can be obtained by means of crushing;

[0079] FIG. 5 an example of a platelet-shaped magnetic effect pigment according to the invention; and

[0080] FIG. 6 a conventional platelet-shaped magnetic effect pigment according to the prior art, whose magnetic moment extends perpendicular to the normal vector of the thin films.

[0081] FIG. 6 shows a conventional platelet-shaped magnetic effect pigment 13 according to prior art whose magnetic moment extends perpendicular to the normal vector of the thin films. Such effect pigments 13 are commercially available under the trade name OVMI® from the company SICPA, have a platelet-shaped construction and are present in the form of a layer composite which includes two layers of optical effect layers, e.g. in each case a color-shifting layer system with absorber/dielectric/reflector construction, and a magnetic layer embedded in between. The optical effect layers each represent a color area. The side areas of the pigment 13 are more or less uncolored. The magnetization of the magnetic pigment 13 is referred to by the formula symbol “m”. If a magnetic field with a field strength having the formula symbol “H” is applied, the pigments 13 are aligned such that their magnetization is parallel to the field vector, if possible (see FIG. 6). As a consequence, the magnetic pigments 13 can rotate about axes parallel to their magnetization “m”. The use of such magnetic pigments 13, e.g. when printing a value document, thus leads to a substantially uniform alignment of the pigments 13 in one direction, while the alignment of the pigments 13 in another direction is substantially randomly distributed. Thus, when viewing a value document obtained in this way, it is not always a color area of the pigment 13 that points upwards in the direction of the viewer. This leads to a widening of the light reflection and to a decreased brilliance and sharpness of the optically variable effect.

[0082] FIG. 5 shows an example of a platelet-shaped magnetic effect pigment 12 according to the invention, whose magnetic moment “m” is aligned perpendicular to the platelet plane. If a magnetic field with a field strength having the formula symbol “H” is applied, the pigments 12 are aligned such that their magnetization is parallel to the field vector, if possible. Just as with the magnetic effect pigments 12 known in the prior art, a degree of freedom remains: the platelets can rotate about an axis parallel to their magnetic moment without changing their potential energy in the magnetic field. In contrast to the magnetic pigments 13 known in the prior art, however, the rotation in the case of the pigments 12 according to the invention has no significant influence on the reflecting properties of the pigments 12. Consequently, the reflecting properties can be better controlled. In the case of the magnetic pigments 13 known in the prior art, the viewer sees a plurality of small pigments, each with a substantially random brightness. The security elements obtained in this way consequently have a granular or a, so to speak, “noisy” optical texture. In comparison, homogeneously glossy areas can be produced by means of the pigments 12 according to the invention. In this way, so-called micro-mirror bulge effects can be achieved, for example.

[0083] The platelet-shaped magnetic effect pigment 12 according to the invention, shown in FIG. 5, has a sandwich-like layer construction with a specific magnetic layer as a central layer, which is provided with an optical functional layer both on the front side and on the back side. In the present example, the two optical functional layers are identical and are each formed by an interference layer construction with a reflective layer (e.g. an Al layer), a dielectric layer (e.g. an SiO.sub.2 layer) and an absorbent layer (e.g. a Cr layer). The effect pigment 12 thus has a symmetric layer construction with the layer sequence: absorbent layer-dielectric layer-reflective layer-magnetic layer-reflective layer-dielectric layer-absorbent layer.

[0084] With reference to FIGS. 1 to 4, the production of the platelet-shaped magnetic effect pigment 12 according to the invention is described below in accordance with FIG. 5. FIGS. 1 to 3 illustrate in particular the manufacture of the magnetic layer.

[0085] FIG. 1 shows a column-shaped nanostructure made of magnetic material produced above a substrate 1 by means of glancing angle deposition (GLAD), with the columns 2 being oriented perpendicular to the substrate plane. The magnetic material used is, e.g., α-Fe.sub.2O.sub.3 (haematite).

[0086] The column-shaped nanostructure shown in FIG. 1, after detachment from the substrate, is provided as a magnetic layer 5 for producing the effect pigments according to the invention (see FIG. 3). The arrows 6 shown in FIG. 3 each illustrate the magnetic moment of the individual magnetic columns within the nanostructure.

[0087] The magnetic layer 5 obtained is provided, according to FIG. 4, both on the front side as well as on the back side by means of vapor deposition with respectively one color-tilting interference layer construction which has a reflective layer 9 (or 9′), a dielectric layer 10 (or 10′) and an absorbent layer 11 (or 11′). FIG. 4 shows a section of the layer construction 7 obtained in this way, starting from which the platelet-shaped magnetic effect pigments 12 according to the invention can be obtained by means of crushing.

[0088] According to a modification of the above-described manufacture of an effect pigment according to the invention, the magnetic layer 5 shown in FIG. 3 is not based on the column-shaped nanostructure shown in FIG. 1, in which the magnetic columns 2 are oriented perpendicular to the substrate plane, but on the column-shaped nanostructure shown in FIG. 2, in which the magnetic columns 4 are inclined towards the plane of the substrate 3.

[0089] Furthermore, according to a further modification of the above embodiments, the column-shaped nanostructure of the magnetic material can be obtained using the oblique angle deposition (OAD) technique instead of the glancing angle deposition (GLAD) technique.

EFFECT PIGMENT, PRODUCTION METHOD, VALUE DOCUMENT AND PRINTING INK

Inventors

Cpc classification

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B05D5/065

PERFORMING OPERATIONS; TRANSPORTING

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C09D11/50

CHEMISTRY; METALLURGY

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B41M3/14

PERFORMING OPERATIONS; TRANSPORTING

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C09C1/0021

CHEMISTRY; METALLURGY

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C09D11/037

CHEMISTRY; METALLURGY

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B05D3/207

PERFORMING OPERATIONS; TRANSPORTING

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C09C1/0015

CHEMISTRY; METALLURGY

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B42D25/29

PERFORMING OPERATIONS; TRANSPORTING

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B42D25/23

PERFORMING OPERATIONS; TRANSPORTING

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B42D25/41

PERFORMING OPERATIONS; TRANSPORTING

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B42D25/369

PERFORMING OPERATIONS; TRANSPORTING

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H01F1/0551

ELECTRICITY

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C01P2006/42

CHEMISTRY; METALLURGY

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B41M7/0072

PERFORMING OPERATIONS; TRANSPORTING

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C09C1/0078

CHEMISTRY; METALLURGY

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C09D11/101

CHEMISTRY; METALLURGY

International classification

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C09C1/00

CHEMISTRY; METALLURGY

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B41M3/14

PERFORMING OPERATIONS; TRANSPORTING

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B41M7/00

PERFORMING OPERATIONS; TRANSPORTING

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B42D25/369

PERFORMING OPERATIONS; TRANSPORTING

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C09D11/037

CHEMISTRY; METALLURGY

Classification Explorer

C09D11/101

CHEMISTRY; METALLURGY

Classification Explorer

C09D11/50

CHEMISTRY; METALLURGY

Classification Explorer

H01F1/055

ELECTRICITY

Abstract

Claims

Description