DE19860093A1 - Authenticity feature combination for documents of value - Google Patents

Abstract

The invention relates to a valuable document, such as a banknote, identification card, or the like, comprising a first machine-verifiable, physical or chemical feature and comprising a second machine-verifiable, physical or chemical feature, whereby the first and second verifiable features can be machine-verified separately. The valuable document loses the first verifiable feature at a first temperature, and the valuable document loses the second verifiable feature at a second temperature which differs from the first temperature. To this end, the invention provides a solution with which the unequivocal identification of a valuable document should be able to be carried out both using the valued document itself as well as using the ashes thereof without, however, making it possible to illegally recover the authenticity feature for reproducing valuable documents.

Description

The invention relates to a combination of materials with two machine testable Properties for the authenticity assurance of value documents, the Ver Use of this combination of materials to ensure the authenticity of your documentary elements, a value document with two authenticity features, each with ma Rapidly testable physical property and a method of manufacture such value documents as well as a procedure for checking the authenticity of charred material or ash.

Documents of value in the sense of this invention can be all documents which must be protected from imitation. In particular fall under it Banknotes, stock papers, identity papers, but also identity cards, Smart cards and the like. You can use cellulose, Cotton material or based on plastic material or from a A combination of several of these materials can be produced.

To protect the value documents against imitation, the value do documents with little or no effort imitable authenticity features. As authenticity features can z. B. fluorescent materials, magnetic particles and others based on their Detectable substances used for specific physical properties become. Such are authenticity features that can be verified by machine Features designated, which are particularly intended to ge to be checked, in contrast to human, in particular to be checked visually the characteristics. Such human characteristics are e.g. B. Watermark, Guil punch, intaglio printed images and the like. For one mechanical testing, for example, magnetic materials are suitable very good. You can get the security in the form of magnetic particles are added. Such magnetic particles can be hard magnetic, d. H. a permanent measure after their magnetization  generate a magnetic field, or they can be soft magnetic, i.e. H. only under Exposure to an external excitation magnetic field magnetization exhibit.

But also the use of luminescent markings as ma Rapidly verifiable authenticity feature is from the prior art widely known. A distinction is made between fluorescent substances that characteristic emission radiation only under excitation radiation emit, and phosphorescent substances, even after switching off the Anre emit radiation over a longer period of time. Ver Different properties of the luminescent substances can be authenticated can be used, such as excitation and emission spectra tren, visibility / invisibility of the emission, a possible afterglow duration and its half-life, narrowband / broadband emission. On Due to these many evaluation criteria, the security against counterfeiting becomes too additionally increased, since the counterfeiter does not know which property is evaluated and must therefore be adjusted by him.

Luminescent substances are often used, which are only in a very emit narrow wavelength range, such as rare earth bonds. They have broadband emitting luminescence have the advantage that their emission spectra are more characteristic than that of other fabrics, which is why they are used for machine authenticity higher security value can be awarded. To make sure Emissi can increase the value of broadband emitting substances onspectrum can be modified in a characteristic manner, as is the case with is described for example in DE 30 20 652.  

For criminological purposes, it is helpful if for the protection of Documents feature substances are used that even after Ver burning of the document are still detectable to be able to ensure that an unrecognizable combustion residue is actually from real Documents. On the other hand, it must be prevented that the Characteristic substances do not contain ashes from burnt documents of value recovered and used to create counterfeits.

The object of the present invention is therefore to propose a solution gene with which the unique identification of a value document both based on the value document itself as well as on its ashes should be feasible without, however, an illegal recovery of the real feature to enable the creation of new value documents.

This task is characterized by the characteristics of the subordinate patent sayings solved. Further training can be found in the subclaims.

The invention is based on the finding that the opposite goals are set by providing different physical or chemical eggs properties can be achieved that can be tested separately and change or disappear at different temperatures. Accordingly, the document of value according to the invention has at least two mechanically testable physical or chemical properties, which can be detected separately from each other, the document of value min most of all a machine-testable property at a first temperature loses and possibly also the other testable property in one second temperature, which differs significantly from the first.  

The testable properties are preferably located at the same location and / or are based on the same physical or chemical phase noun. Unless they are properties that are not the same physical phenomenon, they can have different properties ten of a single feature substance, at different temperatures structures at least partially disappear or change measurably. in the For the rest, two feature substances are preferably used, each have one of the testable properties.

When selecting the testable properties is fer according to the invention ner to take into account that in connection with the combustion of Two temperature ranges must be observed. For one, the Self-firing temperature, d. H. the temperature at which the value document, for example, a banknote set on fire by a lighter, under burns atmospheric conditions, and on the other hand the usual ver Temperature of the documents of value in high temperature furnaces. Because Valuable documents, if due to the degree of pollution or are no longer fit for damage from the issue the places in high temperature furnaces with oxygen support or the same destroyed. The usual destruction temperature is around 1000 ° C and more. The self-firing temperature, on the other hand, is between two 400 ° C and 500 ° C well below the annihilation temperature.

Since the destruction of valuable documents takes place in large quantities, must according to the invention in any case ensure that unauthorized persons none from the combustion residues of the destroyed value documents Can regain authenticity features that are a real imitation Allow documents of value.  

Accordingly, the testable properties (E ₁ , E ₂ , etc.) that can be used in the context of the invention must meet one of the following conditions, T ₁ denoting the self-firing temperature and T ₂ the destruction temperature:

1st possibility

The value document loses the first property E ₁ below T ₁ and keeps the property E ₂ above T ₁ and T ₂ .

In this constellation, the temperature-stable, testable property E ₂ can be used to prove that the ash comes from a real document of value. However, no statements can be made about the type of combustion - combustion under atmospheric conditions or destruction.

2nd possibility

The document of value retains the properties E ₁ and E ₂ above the temperature T ₁ and loses the property E ₁ below the temperature T ₂ while maintaining the property E ₂ also above T ₂ .

In this case, it is not only possible to determine on the basis of property E ₂ that the ashes come from a real value document, but also in what way the value document was burned. Because the ash still has both properties E ₁ and E ₂ , the document of value was burned under atmospheric conditions, whereas the ash only has property E ₂ , the document of value was at least exposed to the destruction temperature.

3rd possibility

The document of value loses the property E ₁ under T ₁ and the property E ₂ under T ₂ .

In this case, the ashes of a document of value that has been burned above the destruction temperature have neither property E ₁ nor property E ₂ . The ash produced during official destruction is therefore neutral with regard to the characteristics. If the ash still has the property E ₂ , this is considered as evidence of the combustion under atmospheric conditions.

4th possibility

The value document retains the properties E ₁ and E ₂ above T ₁ and loses both properties below T ₂ .

Here too, combustion can be verified under atmospheric conditions, so that documents that have been accidentally burned are still recognized as real value documents and can, under certain circumstances, be exchanged for undamaged documents. If the ash has neither property E ₁ nor property E ₂ , then no statements can be made in this case as to whether it was originally a genuine document of value.

For the purpose according to the invention, the most varied effects, such as e.g. B. luminescence, magnetism, conductivity, chemical reactions settable. It is only essential for the invention that at least two physi calic or chemical properties can be evaluated, of which at least at least irreversibly change above a certain first temperature changed or completely disappears and the second property above the first temperature is maintained.

According to a preferred embodiment, the document of value can two luminescent substances are provided which are their luminescent egg lose properties at different temperatures. Particularly suitable net are combinations of organic and inorganic luminescence substances because organic luminescent substances have their luminescent property riding at low temperatures while losing a variety of anor ganic luminescent substances are temperature stable.

Various dyes come as unstable organic luminescent substances fe, such as methylene blue, rodamine, anthrazine, quinazolone, benzozazine or the like into consideration, but also rare earth chelates or rare earth Acetonates. Inorganic stable luminescent substances used in the Er find application, are rarely earth-doped host lattices. As Host lattices are preferably calcium tungstate, yttrium garnet, Yt trium vanadate, yttrium oxysulfide or the like is used. For invisible re codings, whose emission wavelength is in the IR range, are the rare earths neodymium, ytterbium, praseodymium, erbium or holmium preferably used in chrome or iron-containing host grids. The rare he the containing compounds are preferably used because their Emission bands are very narrow and therefore very good for a machine suitable for testing.  

However, instead of the unstable organic luminescent substances inorganic unstable luminescent substances, such as silver or copper / cerium doping Zirconium sulfide can be used.

According to a further embodiment, different magnetic materials can also be used which either irreversibly change their magnetic behavior at certain temperatures or lose them completely. Iron oxide (Fe ₃ O ₄ ), black chromium oxide and barium ferrite are examples of temperature-stable magnetic materials with medium-hard to hard magnetic properties.

On the other hand, metallic magnetic materials such as iron or cobalt in powder form or in the form of thin layers are not very temperature-resistant. They show soft to hard magnetic properties. Cobalt-iron or nickel-iron alloys are also soft magnetic and highly flammable. Another example of a very hard magnetic, yet easily flammable material is cobalt samarium (SmCo ₅ ).

The easily flammable magnetic materials lose at low Temperatures completely change their magnetic properties or change their ma genetic behavior in a very characteristic way. The magnetic egg Properties of temperature-stable magnetic materials, on the other hand, remain unchanged different.

If the value documents are documents of a series, the however, different counter values are assigned - such as B. Banknotes with different denominations - so it can also be advantageous be different, the different denominations with different properties to provide pairs of shafts so that a combustion check  residues not only allow statements about "real" or "wrong", but also about the special category, e.g. B. Denomination of the document of value. This would be particularly useful for banknotes because of the combustion residues are often no longer recognizable, which denomination it is originally acted but the owner wants to demonstrate that the ashes come from certain banknotes.

The feature substances can be introduced in various ways If the document of value is made of paper or has a paper layer, so can the feature substances during papermaking the pulp mixed evenly or onto the finished, still wet paper web in be areas sprayed on, printed on or otherwise opened or closed to be brought.

If the value document has plastic material, the characteristics can the plastic material also beige when processing plastics mixed and processed with this to films or fibers. These slides or fibers can then be used directly as a value document or for the Production of value documents can be used. It is also there possible to cut the film into strips, for example, as a security thread embedded in the paper during papermaking. It is also possible Lich to provide mottled fibers or planchettes with the feature substances. Here too, as with the security thread, the fabrics can enter the material of the mottled fibers or planchettes themselves introduced in volume or on printed on the surface or dyed with them in a dye bath his.

Another option is to use plastic films as a cover film to use an ID card or passport.  

Alternatively, the document of value can also have one of the features printing ink containing substances. The feature substances can however, it can also be included in various printing inks. Anyone can any printing process can be used, especially gravure printing ren, thermal transfer printing, hot stamping, screen printing ren.

The following examples briefly outline the range of possibilities be interpreted.

example 1

The paper pulp for the production of security paper is admixed with two luminescent substances which have a different emission spectrum before sheet formation. The luminescent substance that is temperature-stable according to the invention is Y ₃ Al ₅ O ₁₂ : Tb, which shows a very characteristic emission spectrum in the green wavelength range. ZnS: CuCl is used for the less stable luminescent substance, but its emission, which is also in the green spectral range, disappears at temperatures of 700 ° C. The emission spectra of the two luminescent substances are both in the green spectral range, but they differ so much with regard to the course of their emission spectra that they can be detected separately from one another by measurement technology.

If the finished paper is lit and burned under normal atmospheric conditions, both luminescent substances remain detectable. The less temperature-stable ZnS phosphor is only destroyed when the paper is burned in a combustion furnace at over 1000 ° C. The inorganic, terbium-doped luminescent material, on the other hand, survives these temperatures undamaged, so that the ash can be recognized from the characteristic spectrum of Y ₃ Al ₅ O ₁₂ : Tb as originating from real documents, but in which it can also be demonstrated that it is not below normal atmospheric conditions.

Example 2

Two luminescent substances are added to a printing ink have different emission spectrum. At the tempera The stable luminescent substance is a zinc silicate: Man gan (CD 112 from Allied Signal), which is in the green wavelength range richly emitted. For the unstable luminescent substance, one euro pium chelate compound from the class of thenoyl trifluoroacetonates (CD 335 from Allied Signal) used in the red wavelength fluorescent area.

If the color is applied to any carrier, you get as visual impression of the mixed color of both fluorescent pigments. If the carrier is in an incinerator temperatures above When exposed to 800 ° C, the europium chelate compound is destroyed. The In contrast, inorganic fluorescent material survives this temperature undamaged so that the ashes are based on their characteristic fluo spectrum as can be recognized by real documents. At the same time, it can also be demonstrated that they are not under nor paint atmospheric conditions.  

Example 3

A resin matrix, e.g. B. based on the polyaddition of more functional isocyanates, melamine and benzamide becomes an anorga African fluorescent substance, yttrium oxide: Europium (CD 106 from the company Allied signal) together with an organic fluorescent substance the class of benzothiazoles (CD 333 from Allied Signal) yellow-green fluorescence added during plastic synthesis. This gives a feature substance in the form of a powder, which is under UV excitation has an orange fluorescence. Will that be so? provided luminescent pigment mixed with an ink and this Applied on paper, you get a paper with orange fluorescence. If the paper is in an incinerator temperatures above When exposed to 800 ° C, the organic fluorescent substance is destroyed. The In contrast, inorganic fluorescent material survives this temperature undamaged so that the ashes are based on their characteristic fluo spectrum as can be recognized by real documents. Here too, however, it can be demonstrated that the ashes are not un normal atmospheric conditions. The ash shows a red fluorescence in this case.

Example 4

Two different offset colors are combined with one inorganic fluorescent pigment, calcium silicate: manganese lead (CD 110 of Allied Signal), which has an orange fluorescence or with an organic pigment based on anthranilic acid (CD 329 der Allied Signal), which has a blue fluorescence, mixed. The printing inks thus obtained are alternately in the form of a  Coding applied to a film, this then in fine Cut strips and in the form of a security thread at Pa pier manufacturing used. The security marked in this way exposed to temperatures above 800 ° C in an incinerator, the organic fluorescent substance is destroyed. The inorganic fluo On the other hand, the reagent survives this temperature undamaged that the ash based on its characteristic fluorescence spectrum as can be recognized by real documents. Leaves at the same time but also prove that they are not under normal atmospheric conditions conditions. In this case, the ash has one orange fluorescence.

Example 5

The fluorescent substances used in Example 4 are in this Fall once in a printing ink and on the other hand in paper, as in Example 1 described, mixed. After applying the print color on the paper produced in this way, a document is obtained which is a orange fluorescence in the print and a blue fluorescence in the paper having. The security so marked will be in a scorch exposed to temperatures above 800 ° C, the organic Fluorescent substance destroyed. The inorganic fluorescent about on the other hand, this temperature is undamaged, so that the ash is on based on their characteristic fluorescence spectrum as real Documents can be recognized. In this case, the ash shows ne orange fluorescence.  

Example 6

A printing ink for gravure, tampon or screen printing with cobalt samarium powder (SmCo ₅ ) is produced. For this purpose, 1 part of vinylite as a binder is mixed with 1 to 2 parts of magnetic pigment and 0.5 to 3 parts of ethyl acetate as a solvent. The amount of solvent depends on the printing process used. If the ink is printed in gravure printing, more solvent is required, but less for the production of a screen printing ink.

It becomes a second printing ink of the above-mentioned composition made with carbonyl iron powder (99% Fe). Both prints ben, if necessary with the addition of further color pigments te, printed as a barcode on a plastic film, which is then printed in Security threads is cut. These threads are used at Pa pier manufacturing completely embedded in the paper.

This combination of cobalt samarium and carbonyl iron offers a high level of protection against counterfeiting since it is not commercially available and has very characteristic magnetic properties. Cobalt samarium is with a remanence in the range of 40,000 Oe ex Extremely hard magnetic, while carbonyl iron is only a Rema has less than 10 Oe.

When the security is burned under atmospheric conditions, the cobalt samarium is converted into completely non-magnetic oxides and the carbonyl iron becomes iron oxides Fe ₂ O ₃ and Fe ₃ O ₄ with a significantly higher remanence compared to carbonyl iron of approx. 200 Oe to 400 Oe.

The hard magnetic properties go through the scalding lost power, while the soft magnetic, albeit in something changed form, are retained.

Example 7

The magnetic pigments named cobalt samarium and in Example 6 Carbonyl iron can also use offset, letterpress or steel engraving colors be added. For this, 0.3 to 1 part of magnetic pigment and 1 part linseed oil varnish. The varnish is depending on the pressure proceed with more or less linseed oil thinner (offset) or firmer (Steel engraving) rubbed.

With these inks, a security is either the same Place or in various places in any characters or patterns printed.

Testing of charred or burned material that is suspected derives from a document of value according to the invention is carried out using the testable physical or chemical properties of the feature fabric. The testable property is automatically evaluated and with stored reference values compared. Supposedly a document of value accidentally burned under atmospheric conditions so the measured values of the testable property with the to waiting reference values for the temperature range above approx. 400 to 500 ° C and below approx. 1000 ° C compared. Only if the measured values and the reference values match, it is a real value document.  

At the same time, it can also be proven whether the supposed value document was actually burned under atmospheric conditions. voices namely the measured values with the reference values above the ver temperature of approx. 1000 ° C, this can be an indication to be that ashes fraudulently from a pre-extermination removed and declared as accidentally burned document of value was to issue this against an intact value document at the to trade the job.

To make the identification of the ashes even more secure, the Feature substances or characteristic components of the feature substances with Using trace analysis methods and their concentration be determined. For example, methods such as Atomic Absorption Spectroscopy (AAS), Atomic Emission Spectroscopy (AES) in the discharge spectrum, electron beam excited X-ray emission spec topology (EBMA).

In these trace analysis methods, in particular the Merk Colorants detected that in the ashes from not according to the invention secured documents are not included. In the case described above Game 1 will be the materials yttrium, terbium, zinc and copper as well as the concentration ratio of these substances. In example 7 on the other hand, the presence of the substances iron, cobalt and samarium checked and the concentration ratio of these substances among themselves evaluated.

Claims (35)

1. document of value, such as bank note, identity card or the like,

• - With at least a first mechanically testable physical or chemical property and
• with at least one second mechanically testable physical or chemical property,

in which

• both are physical or chemical properties of at least one feature substance,
• - the first and second testable properties can be checked separately by machine,
• the feature substance loses the first testable property at a first temperature or the property changes measurably, and
• - The feature substance retains the second testable property at the first temperature and possibly loses it at a second temperature that differs significantly from the first temperature.

2. Value document according to claim 1, characterized in that the first and second testable properties in the same place, but ge have them checked separately by machine. 3. Value document according to claim 1 or 2, characterized in that the testable properties are based on the same physical effect. 4. document of value according to at least one of claims 1 to 3, characterized characterized in that the value document at least a first and two ten feature substance, each of the first and second physical properties.   5. document of value according to at least one of claims 1 to 4, characterized characterized in that the first temperature is less than or equal to the eigen burning temperature of the value document. 6. document of value according to at least one of claims 1 to 4, characterized characterized in that the first and / or second temperature is greater than that Is the internal firing temperature of the value document. 7. document of value according to at least one of claims 1 to 4, characterized characterized in that the first and / or second temperature is greater than that The firing temperature of the document of value, but less than a Vernich are temperature. 8. document of value according to at least one of claims 1 to 4, characterized characterized that the second temperature is greater than a vernich temperature of the value document. 9. Value document according to at least one of claims 1 to 8, characterized ge indicates that the self-firing temperature of the document of value is 400 ° C is up to 600 ° C, preferably about 500 ° C. 10. document of value according to at least one of claims 1 to 9, characterized characterized that the annihilation temperature be 1000 ° C or more wearing. 11. document of value according to at least one of claims 1 to 10, characterized characterized in that the first feature substance is an inorganic and the second feature substance is an organic luminescent substance.   12. document of value according to claim 11, characterized in that the organic luminescent substance is methylene blue. 13. document of value according to at least one of claims 1 to 10, characterized characterized in that the first and the second feature substance each are inorganic luminescent substance. 14. document of value according to at least one of claims 11 to 13, characterized characterized that the inorganic luminescent substances rarely earth doped te host lattice included. 15. document of value according to one of claims 1 to 14, characterized records that at least one of the testable properties on or in an egg nem security thread or mottled fibers is arranged. 16. document of value according to at least one of claims 1 to 15, characterized characterized in that at least one of the testable properties in we at least one printing ink is included, which is printed on the value document is printed. 17. document of value according to at least one of claims 1 to 16, characterized characterized in that at least one of the testable properties in the Basic material of the value document is included. 18. Value document according to at least one of claims 1 to 17, characterized characterized that the basic material of the value document essentially Chen consists of paper, preferably cotton paper.   19. Value document according to one of claims 1 to 17, characterized distinguishes that the basic material of the value document essentially a plastic material. 20. Combination of substances for the authenticity of documents of value with

• a first feature substance with a first testable physical property, and
• a second feature substance with a second testable physical property,

in which

• - the first and the second testable property can be tested separately,
• the first feature substance loses the first testable property at a first temperature, and
• - The second feature substance keeps the second testable property unchanged at its first temperature, but may lose it at a second temperature that is significantly different from the first temperature.

21. A combination of substances according to claim 20, characterized in that the first and second testable property on the same physical phase nouns are based. 22. Combination of substances according to claim 20 or 21, characterized in that the first feature substance is an inorganic and the second feature are an organic luminescent substance. 23. Material combination according to claim 22, wherein the organic luminescence is methylene blue.   24. Material combination according to claim 20 or 21, characterized in that the first feature substance and the second feature substance an inorganic are luminescent substances. 25. Combination of substances according to at least one of claims 22 to 24, there characterized in that the inorganic luminescent substance is rare includes doped host lattice. 26. Combination of substances according to claim 25, characterized in that the Rare earth is selected from the group of substances neodymium, ytterbium, Praseodymium, heiress and holmium. 27. Combination of substances according to claim 25 or 26, characterized in that that the host lattice contains substances from the group chromium and iron are selected. 28. Material combination according to claim 24, characterized in that the second luminescent substance is ZnS: CuCl and the first luminescent substance is Y ₃ Al ₅ O ₁₂ : Tb. 29. Use of a material combination according to at least one of the claims che 20 to 28 for the authenticity of documents of value. 30. A method for producing documents of value, according to at least one nem of claims 1 to 20, characterized in that the first and the second verifiable property with the value document firmly connected the.   31. The method according to claim 30, characterized in that the value document is provided with a first and second feature substance, the each have the first and second testable properties. 32. The method according to claim 31, characterized in that at least one of the feature substances as an additive in a security thread, in Melierfa or the value document material is introduced. 33. The method according to claim 31, characterized in that at least one of the characteristic substances mixed with a printing ink and on the Wertdo document is printed. 34. The method according to at least one of claims 30 to 33, characterized ge indicates that the first and second feature substance as a mixture are processed. 35. A method for testing charred or burned material, which presumably comes from a value document according to at least one of claims 1 to 19, characterized by the following steps:

• Determining the temperature to which the value document was exposed,
• - checking the physical properties,
• Retrieving stored reference values depending on the temperature to which the value document was exposed,
• - Comparison of the reference values with the measured values.