DE2421469C2 - Security document with a magnetizable recording layer and method for producing a security document - Google Patents

Description

a) the magnetizable material is barium ferrite and at a number of selected locations (16, 18, 36, 50) in the recording layer (14, 28, 40, 58) it is physically different with respect to the physical orientation of the magnetizable material (44) aligned to a reference location (edge 20) in the recording layer (14, 28, 4O ₅ 58);

b) the selected points (16, 18, 36, 50) form a pattern that is a permanent signal track represents from which a predetermined recurring signal can be generated

2. Security document according to claim 1, characterized in that the pattern is a recurring one Pattern is.

3. Security document according to claim 2, characterized characterized in that at each S'.elle (16, 18, 36, 50) the magnetizable material (44) is physically different is aligned where there's one going continuously changing permanent signal track is generated, from which a predetermined and continuously changing signal can be generated.

4. Security document according to one of claims 1 to 3, characterized in that the magnetizable Material (44) in the remaining part (32, 34, 46, 48) of the recording layer (14, 28, 40, 58) outside of the selected locations is physically aligned in a single direction, and that the magnetizable Material (44) in more than two selected locations (16,18,36,50) in an area that is not used for a recording, different from the aforementioned single orientation is physically aligned.

5. Security document according to claim 4, characterized in that each of said selected ones Places (16, 18, 36, 50) consists of a single section in which the magnetizable material (44) physically perpendicular to the orientation of the material in the remaining part of the recording layer (14, 28,40,58) is aligned.

6. Security document according to one of claims 1, 4 or 5, characterized in that the selected Places (16, 18, 36, 50) form a non-recurring pattern that creates a permanent signal track represents, from which a predetermined, non-recurring signal can be generated.

7. A method for producing a security document that is magnetically detectable and permanent having fixed information pattern, wherein a paper sheet-like material with a non magnetisicrbarcn substrate and with a layer of a substantially uniform dispersion magnetically anisotropic and magnetizable particles is provided in which the particles initially

are freely rotatable, the magnetizable particles are physically aligned in the layer, after which the particles are permanently immobile are made, characterized in that barium ferrite is selected as the magnetizable particle and the magnetizable particles (44) at said selected locations (16,18,36, 50 ^ physically are oriented differently than the magnetizable particles (44) at a reference point, wherein the permanently fixed information pattern is generated, and that on the paper sheet-like material Visible markings (17, 70) are attached that indicate the intended use of the security document are characteristic.

The invention relates to a security document having a magnetizable recording layer which has a Contains uniformly dispersed, magnetizable and magnetically anisotropic material as well as a magnetic identifiable and permanently fixed information pattern and visible, for the intended use has characteristic identification elements.

The invention also relates to a method of production a security document, which is a magnetically determinable and permanently fixed information pattern has, wöbe; a paper sheet-like material with a non-magnetizable background and with a Layer of a substantially uniform dispersion that is magnetically anisotropic and magnetizable Particles is provided in which the particles are initially freely rotatable, the magnetizable particles in the layer are physically aligned, and thereafter the particles are permanently immobilized will.

A security document should be understood as an iviedium be that preferably at least two Irsformations contains, namely visible, relating to the intended use of the security document Identifications, and a permanently fixed information pattern, such as a coding pattern, which is usually is hidden and difficult to reproduce, so that forgery is difficult or prevented.

There are security documents with magnetic coding such as. B. tickets, credit cards and the like known in which a uniform dispersion of physically uniformly aligned magnetic Particle is magnetically encoded to provide magnetically detectable information patterns. So is z. B. according to DE-OS 19 48 855 a magnetic coding on two parallel tracks of a magnetic layer alternately upset.

From US-PS 36 43 064 there is also a security document showing credit card showing in one part a square area from one Has magnetizable material which is optionally magnetizable to form a coded pattern.

According to US-PS 34 53 598 a credit card is known, the hidden magnetic elements on certain Has places, d. H. a uniform dispersion of magnetic particles is not provided here. Known is finally a security document with a ma

b ^r > magnetic recording layer (DK-AS 19 31536) in which a random pattern, normally invisible to the eye, of fine / given ferromagnetic !! Particle is used. i.e. the latter is not the same-

Tiäßig in the magnetizable! Recording layer dispersed.

The invention is based on the object of a security document and to specify a method for its production according to the type mentioned at the beginning in such a way that that a security document is available in which one Magnetically determinable fixed information is registered like a coding pattern so that a Modification through the use of conventional recording methods is excluded.

According to the invention, this object is achieved by the combination of the following features:

a) the magnetizable material is barium ferrite and at a number of selected locations in the recording layer physically different in with respect to the physical orientation of the magnetizable material at a reference point in aligned with the recording layer;

b) the selected locations form a pattern which represents a permanent signal trace from which a predetermined one recurring signal is audible

The method according to the invention is characterized in that the magnetizable particles are barium ferrite is chosen and the magnetizable particles to the named selected points are physically aligned differently than the magnetizable particles at a reference point, wherein the permanently fixed information pattern is generated, and that on the paper biatl-like Material visible markings are affixed for the intended use of the security document are characteristic.

Advantageous further developments of the security document according to the invention result from the subclaims.

The coding pattern entered in the security document, the one magnetically determinable, fixed Represents information cannot be changed by conventional recording methods.

The security document and the method according to the invention r \ x whose preparation we ^r the now explained with reference to drawings. In the latter are

1 shows a diagrammatic representation of the security document,

F i g. 2 shows a vertical section through part of the security document, its recording layer contains differently oriented and magnetizable needle-shaped particles,

F i g. 3 shows a vertical section through part of another security document, its recording layer platelet-like magnetizable particles between inner printable layers and outer ones Contains protective layers,

F i g. 4 shows a diagrammatic representation from which the method for producing the security document emerges and

F i g. 5 shows a greatly enlarged cross section through the security document showing the different Alignment of magnetizable particles in a sheet material that is used as part of a security document should be used.

Fig. 1 shows the Siclierbeitsdokument 10, which consists of a Base 12, a recording layer 14 with uniformly dispersed, magnetically anisotropic and customizable particle-fi and an outer layer 15 consists of visible label elements 17 Evenly dispersed means that the part The density of the particles per unit area within the layer is approximately constant, even if the particles are oriented differently in different places. The particles point at selected places 16 and 18 show a different orientation with respect to a reference point, for example on a Edge 20 of the security document 10 be located

ίο can. Those shown at selected locations 16 and 18 Double arrows are intended to indicate the direction in which the magnetizable particles can be moved without difficulty can be magnetized. Anisotropic particles easily become parallel to the direction in any direction magnetized by their easy magnetizability and exhibit a higher remanence than with one magnetization due to the effect of the given field in another Direction. The different armors of magnetization or the magnetic field are only simple Arrows indicated

In one embodiment of the security document, magnetizable particles that do not adhere to the selected locations 16 and 18 of the recording layer 14 are provided, do not have a specific orientation. On the other hand, the magnetizable Particles in all areas of the recording layer 14 outside of the selected locations 16 and 18 oriented so that they are located in an easily magnetizable direction, as indicated by arrow 22 is indicated

Magnetic anisotropy in particles of a magnetizable material is in most cases associated with some anisotropic shape or with crystalline anisotropy. For example, hexagonal ferrite materials, such as barium ferrite, are characterized by a high degree of crystalline anisotropy. Such materials are readily available in the form of very small platelets, the crystalline anisotropy leading to easy magnetizability in a direction perpendicular to the plane of the platelets. The platelets can be influenced without difficulty using mechanical and / or magnetic forces, so that the plane of the platelets runs parallel to the surface of the layer 14. In this case, the direction of easy magnetizability would run in the direction of arrow 22. At the selected locations 16 and 18, the platelets in the recording layer 14 are upright and rotated in the desired direction, as shown by the double arrows. The selected locations 16 and 18 kC-nntn in the recording layer 14 have the same distance from one another and form a recurring pattern as a permanent signal track is determined from which a predetermined, recurring signal can be generated. The security document whose Hp g ^r position in relation to the F i. 4 and 5 has the repeating pattern. The selected locations 16 and 18 can also be provided in a non-recurring manner with varying, predetermined spacing or can be oriented in different directions, as in FIG. 1 is shown. A predetermined and non-recurring signal can be generated which represents the pattern of the non-recurring selected locations.

F i g. FIG. 2 shows, in enlarged cross section, part of another embodiment of the security document

24 with a non-magnetizable one! Pad 26, with a recording layer 28 and with a printable layer 29 with visible identification elements can be provided. The particles 30 in the recording layer 28 are shown greatly enlarged. The recording layer 28 contains acicular or elongated gamma-Fe2O3 particles, which in a flexible binder 31 are uniformly dispersed. The recording layer 28 has parts 32 and 34, in which the particles 30 are uniformly oriented in a direction that is both parallel to the surface as well as in the longitudinal extension of the security document 24. Since the shape anisotropy in gamma FejOs particles is predominant, the direction of easy magnetizability is parallel to the longitudinal dimension of the particles. The direction of easy magnetizability in parts 32 and 34 of the record SCiuCni 28 "also runs parallel to the door Surface and a longitudinal dimension of the security document 24. The part 36 represents a selected one Figure in which the particles 30 are still parallel to the surface of the security document 24, but perpendicular are aligned with the aligned particles in portions 32 and 34 of recording layer 28. For the sake of clarity, the transition between part 32 or 34 and the selected point is shown 36 is shown abruptly with respect to the orientation of the particles. Due to the normal divergence of magnetic flux However, the transition takes place over a distance that depends on the characteristics of the directed magnetic field is determined.

Is the security document 24 exposed to a conventional magnetic recording field that runs in the longitudinal extension of the security document, i. h "in the direction of alignment of the particles in the Tsilsn 32 and 34 d ** r ^ AifhnMniycc Anf / ^ 2 ^ ^cr * hipht the particles situated in these parts to be easily magnetized and have a greater remanence than that at the selected location 36, at which the particles are oriented differently for the magnetization field. When the information is reproduced, a signal with a high amplitude is generated which corresponds to the information of the parts 32 and 34, while a signal corresponding to the selected location 36 is generated with a low amplitude.

The in the security document according to F i g. 2 used magnetic recording layers suitably from strips of conventional magnetic recording material embedded in a support or is attached to this, for example to a 0.76 mm thick credit card material. This Material is available in the form of 0.66 mm thick sheets made from 95% by weight polyvinyl chloride - 5% by weight Polyvinyl acetate The printable layer 29 can be added to the composition with the addition of a titanium dioxide pigment the pad can be omitted, creating a printable area. Furthermore can an outer 0.051 mm thick protective layer made of 95% by weight polyvinyl chloride - 5% by weight polyvinyl acetate be bonded to the pigmented layer under the action of heat after it has been labeled The magnetizable recording layers generally consist of a mixture of the magnetizable · material with a non-magnetizable flexible organic binder together with a suitable solvent which Layers are applied to the substrate and exposed to aligning magnetic fields. Usually such a recording layer consists of a uniform dispersion 65% by weight of gamma Fe2Oj particles with a length of about 500 ηm and a diameter of 100 mn and from 35% by weight of a thermoplastic polyurethane binder together with a suitable solvent.

F i g. 3 shows a greatly enlarged cross-section of part of another embodiment of the security document 38 with a magnetizable recording layer 40, with printable layers 41 and 42 and with protective layers 43. In this embodiment, the magnetizable recording layer 40 contains platelet-like particles 44 of barium ferrite, which are in a flexible binder 45 are shown evenly dispersed and greatly enlarged. The particles 44 are aligned in the parts 46 and 48 of the recording layer 40 parallel to the surface of the security document 38, so that the direction of easy magnetizability runs perpendicular to the plane of the security document 38, as in FIG. I is represented by arrow 22. At the selected point 50, the particles 44 are perpendicular, so that the direction of easy magnetizability at the selected point 50 runs parallel to the plane of the security document 38. The greater anisotropy normally found in barium ferrite particles in contrast to the acicular gamma-Fe ₂ O ₃ -TeUChCn, and the easier alignment of the particles brings about an even greater difference in remanent magnetization as a result of the application of a uniform magnetic field to the recording layer 40. The transition between the part 46 or 48 and the selected point 50 can also extend here over a distance which is determined by the characteristics of the aligning magnetic field.

A method for producing the Security document according to FIGS. 1, 2 and 3, in which a base 52 made of non-magnetizable material is unrolled from a supply roll 54 and underneath a feeder 56 is passed, which is a dispersion of magnetizable anisotropic Contains particles in a binder and with suitable solvents. Here, on the base 52 the magnetizable recording layer 58 is applied. A portion of the recording layer 58 becomes then subjected to a magnetic field generated by an alignment device 60, suitably from a section of a pre-magnetized conventional permanent magnetic material based on polymers consists of barium ferrite flakes. Extend over the alignment device 60 tapes made of an oppositely magnetized material 62 and 64 at the alignment device 60, the magnetizable particles at the locations 59 are correspondingly aligned with the magnetic fields. After this, the alignment device 60 is removed to avoid blurring of the oriented particles to be avoided when following the substrate 52 and the recording layer 58 are passed past a rod 66, which is electrically heated in a conventional manner, with the recording layer 58 heated and the solvent evaporated. This has the consequence that the magnetizable Particles are permanently immobile. The alignment device 60 can also be attached to the pad 52 and remain on the recording layer 58 until the particles are permanently unaffected, for example by heating

have been made away, creating an unintended Blurring of the aligned particles is avoided. Thereafter, on the recording layer 58 the printable layer 68, which has visible identification elements 70, is applied. The printable Layer 68 can also consist of a section of self-adhesive B; u, - .. cs, which contains the marking elementsc having.

The following is the preparation of the security policy described using an example:

A 0.10 mm thick sheet of 95% by weight polyvinyl chloride - 5% by weight polyvinyl chloride pigmented with TiO>; it is placed close to an aligning magnetic field source in such a way that a substantial magnetic flux flows through the sheet. A dispersion of 50% by weight barium frilplaitches. which have an average diameter of about 1 to 5 micrometers and a length to thickness ratio of about 7: i, is mixed with 50% by weight of a thermosetting resin - e.g. an isocyanate-terminated urethane prepolymer - as well as with a diamine curing agent and a suitable catalyst, applied to the sheet to a thickness of approximately 0.58 mm and caused to cure in the presence of the lightening field, producing a layer containing a uniform dispersion of the barium ferrite flakes selectively aligned with the flow lines of the field. If a binder with sufficient viscosity is used, the layer need not remain in the field during the remaining part of the curing process. Since there are normally no forces to destroy the alignment, the particles will maintain their alignment. A curing time of 10 hours at a temperature of 25 ^° C. is generally required for complete curing of the layer. After curing, the upper pigrrssp.tisr-Ic layer can be produced by applying a dispersion of TiOrPigment in an identical urethane prepolymer to the layer up to a thickness of approximately 0.012-0.050 mm. A visible lettering can then be applied to one side of the pigmented layer, on which a transparent protective layer is applied that prevents the lettering from being changed. The amount of barium ferrite in the layer can be up to 85% by weight. rotation of the particles is still possible.

F i g. 5 shows, greatly enlarged, the orientation of magnetizable particles in a sheet-like material 72; dns a dispersion of magnetically anisotropic particles in contains a pliable and uncured binder, so that the particles under the action of a Magnetic field are freely rotatable.

The sheet-like material 72 becomes close to an aligning Magnetic field source 76 arranged, which has a recurring pattern of alternating magnetic field poles 77 and 78 has. The magnetic field is strong enough to cause the particles in material 72 to rotate in one direction to effect the lines of magnetic flux. The magnetic field source IC 76 suitably consists of a portion of a pre-magnetized conventional permanent magnetic polymer-based material. The in material 72 contained particles are corresponding to the double parts 74 aligned so that the direction of the easy magnetizability corresponds to the impressed flux lines follows. When using barium ferrite plates, these lie in a plane perpendicular to the double arrows 74. After aligning the particles in material 72, the binder is cured, causing the particles in their orientation are permanently recorded. The flat material encrypted in this way becomes combined with the printable layer and the protective layer to form the security document. Relatively narrow areas of magnetization can be created between neighboring areas (FIGS. 3 and 2) be generated that the distance 73 between the magnetic field source 76 and the sheet-like material 72 is reduced. Further reductions in the width of the magnetization domains can be achieved, when the sheet-like material 72 is sandwiched between mating magnetic field sources or one of the Magnetic flux concentrating base plate is provided.

The security document is used to check its validity in a corresponding facility of the effect exposed to a rectified magnetic field, which causes a different magnetization of the particles effected at the selected locations according to the orientation of the particles. The differently magnetized selected points are scanned at a sensor when the security document is passed, which generates a signal representing the selected locations. This signal is given with a predetermined one Signal patterns are compared and the authenticity of the security document is thus checked.

For this purpose 2 sheets of drawings

Claims (1)

Patent claims: 1.Security document with a magnetizable recording layer which has a uniformly dispersed, contains magnetizable and magnetically anisotropic material as well as a magnetically detectable material and permanently fixed information patterns and visible, characteristic of the intended use Has label elements, characterized by the combination of the following features: