RU2249504C2 - Protection-attribute combination for important documents - Google Patents

Abstract

FIELD: important documents with protective attributes, combination of matters with two automatically controlled properties for protecting important documents against counterfeit, methods for making such documents and methods for testing authenticity of charred matters and ash.

SUBSTANCE: important document, mainly bank note or person certificate is characterized by use at least of two luminophors whose luminescent properties may be automatically and individually monitored. First luminophore irreversibly losses its luminescent properties at first temperature. Second luminophore irreversibly losses its luminescent properties at second temperature. First and (or) second temperature exceeds natural temperature of burning important document. It allows to identify document according to itself and also according to its ash and prevents possibility of illegal regeneration of materials designed for protecting against counterfeit in order to make duplicates of documents.

EFFECT: enhanced reliability of identifying important documents.

29 cl

Description

The present invention relates to a combination of substances with two automatically controlled properties to protect valuable documents from counterfeiting, to the use of this combination of substances to protect valuable documents from counterfeiting, to a valuable document with two security features, each of which has its own automatically controlled physical property, to a method the production of such valuable documents, as well as to a method for verifying the authenticity of charred material or ashes.

In the context of the present invention, valuable documents are understood to mean all documents that need to be protected from counterfeiting. Such documents primarily include banknotes, securities (shares), identification cards, as well as badges, chip cards, etc. Similar documents can be made on the basis of cellulose, cotton fiber, or on the basis of plastic, or on a combination basis of many similar materials.

Valuable documents for their protection against counterfeiting provide various kinds of security features, which are almost impossible to counterfeit or possible at extremely high costs, essentially not comparable to the cost of the document itself. As such protective features, for example, phosphors, magnetic particles and other substances can be used, which can be detected on the basis of their special physical properties. Automatically detectable security features indicate those features that are designed primarily for automatic control, in contrast to features designed for human verification, primarily visual inspection. The latest security features, designed for human verification, include, for example, watermarks, guilloches, printed images obtained by metallographic printing, etc. For automatic control, for example, magnetic materials are most suitable. Such materials can be added in the form of magnetic particles to the security material at the stage of its manufacture. Such magnetic particles can either be magnetically solid, i.e. to create a constant magnetic field after their magnetization, or magnetically soft, i.e. detect magnetization only when exposed to an external magnetic field.

The widespread use of luminescent labels as automatically detectable security features is also known in the art. In this case, there are distinguished fluorescent substances that can emit characteristic radiation only under the influence of exciting radiation, and phosphorescent substances that can luminesce for a long period of time after the cessation of excitation. Various properties of phosphors can be used as a protective feature, for example, excitation and radiation spectra, radiation visibility / invisibility, possible afterglow duration and half-life of its attenuation, narrow / broadband radiation. The use of all these numerous evaluation criteria can further increase the degree and reliability of the protection of documents from counterfeiting, since the forger does not know which property is being controlled and should therefore be reproduced.

Phosphors that can emit radiation only in a very narrow range of wavelengths, for example, compounds of rare-earth elements, are also often used. The advantage of such phosphors in comparison with phosphors emitting radiation in a wide range of wavelengths is that their radiation has a more characteristic spectrum compared to the emission spectra of other substances, which is why such phosphors should be recognized as more reliable when automatically authenticating documents. In order to increase the reliability of the protection of documents from counterfeiting using substances whose radiation lies in a wide range of wavelengths, their emission spectrum can be changed in a characteristic way, as described, for example, in DE 3020652.

In addition, it should be noted that the use of substances for the protection of documents, which can still be detected even after burning the document, helps to conduct a forensic examination, so that it can actually be established that the original document remains after combustion has been recognized beyond recognition. On the other hand, it is necessary to prevent the possibility of regeneration of the substances used to protect valuable documents from counterfeiting the substances contained in the ashes remaining after burning such valuable documents, and the use of these substances for the manufacture of fake documents.

Based on the foregoing, the present invention was based on the task of finding a solution that would uniquely identify a valuable document both by itself and by its ashes, but at the same time exclude the possibility of illegal regeneration of documents intended to protect against counterfeiting of substances for manufacturing purposes fake duplicate of a valuable document.

The specified objective of the invention is solved with the help of a valuable document, especially a banknote or an identification card, characterized by the presence of at least two phosphors, the luminescent properties of which can be automatically controlled independently of each other, while the first phosphor irreversibly loses its luminescent properties at the first temperature and the second phosphor irreversibly loses its luminescent properties at the second temperature.

According to the invention, the first and / or second temperature exceeds the intrinsic combustion temperature of the valuable document.

In this case, the first temperature may be less than or equal to the intrinsic combustion temperature of the valuable document, and the second temperature exceeds the intrinsic combustion temperature of the valuable document.

It is important to note that the first and / or second temperature exceeds the intrinsic burning temperature of a valuable document, but less than the temperature of destruction of a valuable document.

The second temperature may exceed the temperature of destruction of a valuable document.

The luminescent properties of the phosphors used in the valuable document according to the invention should be able to be automatically controlled in the same place, but independently of each other.

In a preferred embodiment, the intrinsic burning temperature of the valuable document is from 400 to 600 ° C., preferably about 500 ° C., and the destruction temperature of the valuable document is not less than 1000 ° C.

Inorganic phosphor is preferably used as the first phosphor, wherein the second phosphor is an organic phosphor.

In a preferred embodiment, the organic phosphor is methylene blue.

However, it is possible that the first and second phosphors are in each case inorganic phosphors.

Inorganic phosphors in accordance with the invention contain crystalline substances, in the matrix lattice of which there are dopants of rare-earth elements.

According to the invention, at least one of the luminescent properties is present on or in the security filaments or melange fibers of the valuable document, or at least one of the luminescent properties is present in at least one printing ink that is used to seal the valuable document, or at least one of the luminescent properties present in the material-based valuable document.

The base material of the valuable document may be mainly paper, preferably cotton fiber paper, but may be plastic or polymeric material.

The objective of the invention is also solved with the help of the combination of substances proposed therein for protecting valuable documents from forgery, consisting of at least two phosphors, the luminescent properties of which can be automatically controlled independently of each other, while the first phosphor irreversibly loses its luminescent properties at the first temperature, and the second phosphor irreversibly loses its luminescent properties at the second temperature. According to the invention, the first and / or second temperature exceeds the intrinsic combustion temperature of the valuable document.

In this combination of substances, the first phosphor is an inorganic phosphor, and the second phosphor is an organic phosphor.

The organic phosphor is preferably methylene blue.

But options are not excluded when the first and second phosphors are in each case inorganic phosphors.

At the same time, inorganic phosphors contain crystalline substances, in the matrix lattice of which there are dopants of rare-earth elements.

Preferably, the rare earth element is selected from the group consisting of neodymium, ytterbium, praseodymium, erbium and holmium.

Preferably, the matrix lattice contains elements selected from the group consisting of chromium and iron.

It should be noted that in a preferred embodiment, the second phosphor is ZnS: CuCl, and the first phosphor is Y ₃ Al ₅ O ₁₂ : Tb.

The objective of the invention is also solved with the help of its proposed method for the production of valuable documents, which consists in the fact that a valuable document is supplied with the first and second phosphors inextricably linked with it.

In this case, it is preferable to introduce at least one of the phosphors into the protective thread, melange fibers or into the material of the most valuable document as an additive, or mix them with the printing ink used to seal the valuable document, or process the first and second phosphors into their mixture.

The objective of the invention is also solved with the help of the proposed method for checking charred or burned material, which previously supposedly constituted a valuable document, which according to the invention consists in checking the luminescent properties from the memory depending on the temperature to which the valuable document was exposed , cause the reference or control values stored in it, these reference or control values are compared with the measured values and determine whether the temperature at which a valuable document was charred or burned, with its own burning temperature or the temperature of its destruction.

Thus, the main idea of the invention is that it is possible to achieve mutually conflicting goals through the use of various physical or chemical properties that can be controlled independently and which at different temperatures change or disappear. Accordingly, the valuable document proposed in the invention has at least two automatically controlled physical or chemical properties that can be detected independently of each other, while the valuable document loses at least one of its automatically controlled properties at a certain first temperature value, and at a certain second temperature value, significantly different from the first temperature value, under certain conditions it loses and the other is automatically controlled e property.

Preferably, the controlled properties are manifested in the same place and / or based on the same physical or chemical phenomenon or effect. If we are talking about properties that are not based on the same physical phenomenon, then such properties can be different properties of a single controlled substance, which at various temperatures disappear at least partially or change in such a way that such a change can be detected by measuring funds. Otherwise, it is preferable to use two substances, each of which has one of the controlled properties.

When choosing automatically controlled properties according to the invention, it is further necessary to take into account that the burning of valuable documents is possible in two temperature ranges. The first is its own combustion temperature, i.e. the temperature at which a valuable document, such as a banknote set on fire with a lighter, burns in atmospheric conditions, and the usual temperature for the destruction of valuable documents in high-temperature furnaces belongs to the second interval. In the latter case, valuable documents that are subject to withdrawal from circulation due to their high degree of contamination or deterioration are destroyed by the respective issuing institutions in high-temperature furnaces with oxygen purging or in similar conditions. The usual temperature for the destruction of valuable documents is about 1000 ° C or more. In contrast, the intrinsic burning temperature of valuable documents ranges from 400 to 500 ° C, which is significantly lower than the indicated destruction temperature.

Since the volumes of valuable documents destroyed are rather large, according to the invention, it is necessary in each case to exclude the possibility of regeneration by unauthorized persons from the residues of destroyed valuable documents generated after burning, intended to protect documents from counterfeiting substances that would allow forging genuine valuable documents.

Accordingly, the automatically controlled properties (E ₁ , E ₂ , etc.) used according to the invention must satisfy one of the following conditions, with T ₁ denoting its own combustion temperature and T ₂ denoting the destruction temperature.

1st opportunity

A valuable document loses the first property E ₁ below the temperature T ₁ and retains the property E ₂ at temperatures above T ₁ and T ₂ .

With this combination, it is possible to confirm, on the basis of the thermostable controlled property E _2, that the ashes belong to a burnt genuine valuable document. However, it is impossible to draw any conclusions regarding the combustion conditions, i.e. whether the document was burned under atmospheric conditions or at a temperature of destruction.

2nd opportunity

A valuable document retains the properties of E ₁ and E ₂ above the temperature of T ₁ and loses the property of E ₁ below the temperature of T ₂ , while maintaining the property of E ₂ at a temperature above T ₂ .

In this case, on the basis of the E ₂ property, it is possible not only to establish the ownership of the ashes of the burnt genuine valuable document, but also to determine the combustion conditions of the valuable document. If the ash detects both the properties of E ₁ and E ₂ , then the valuable document has burned out under atmospheric conditions, and vice versa, if the ash detects only the property of E ₂ , then this indicates that the valuable document was exposed to at least the temperature of destruction.

3rd opportunity

A valuable document loses property E ₁ below temperature T ₁ , and property E ₂ below temperature T ₂ .

In this case, the ashes of a valuable document, which burned out at the temperature of destruction, does not reveal either property E ₁ or property E ₂ . Thus, the ash generated after the official destruction of the document remains neutral with respect to security features. If the ash, as before, exhibits the property E ₂ , then this indicates the burning of a valuable document in atmospheric conditions.

4th opportunity

A valuable document retains the properties of E ₁ and E ₂ above the temperature T ₁ and loses both properties below the temperature T ₂ .

In this case, it is also possible to establish the fact of burning the document in atmospheric conditions, and therefore it becomes possible to confirm, as before, the authenticity of erroneously burned documents, which, if necessary, can be replaced with undamaged documents. If the ash does not reveal any of the properties of E ₁ and E ₂ , then in this case it is impossible to say that the original valuable document was destroyed.

In the solution proposed in the invention, it is possible to use a wide variety of effects, for example, luminescence, magnetism, electrical conductivity, chemical reactions. The fundamental condition for the invention is only the possibility of analyzing at least two physical or chemical properties, at least one of which irreversibly changes or completely disappears above a certain first temperature, and the second property above this first temperature remains unchanged.

According to one preferred embodiment of the invention, a valuable document may be provided with two phosphors that lose their luminescent properties at different temperatures. Combinations of organic and inorganic phosphors are most suitable in this regard, since organic phosphors lose their luminescent property even at low temperatures, while a large number of inorganic phosphors are thermostable.

As an example of unstable organic phosphors, various dyes can be mentioned, for example, methylene blue, rhodamine, anthrazine, quinazolone, benzosazine, etc., as well as rare earth chelates and acetonates. An example of inorganic stable phosphors that can be used according to the invention are crystalline substances, in the matrix lattice of which dopants of rare-earth elements are present. Moreover, it is preferable to use calcium tungstate, yttrium garnet, yttrium vanadate, yttrium oxysulfide, and the like as crystalline substances. Rare earth elements such as neodymium, ytterbium, praseodymium, erbium or holmium, preferably embedded in a crystal lattice of a matrix of chromium or iron-containing substances, can be used to encode with invisible labels whose radiation wavelength lies in the infrared region of the spectrum. In this case, it is preferable to use compounds containing rare-earth elements, since their radiation has very narrow bands, and therefore such compounds are most suitable for automatic control.

However, instead of unstable organic phosphors, inorganic unstable phosphors can also be used, for example zinc sulfide doped with silver or copper / cerium.

According to another embodiment of the invention, various magnetic materials can also be used, the magnetic properties of which at certain temperatures are either irreversibly changed or completely lost. Iron oxide (Fe ₃ O ₄ ), black chromium oxide, and barium ferrite can be mentioned as examples of thermostable magnetic materials with medium to hard magnetic rigidity.

In contrast, metallic magnetic materials such as iron or cobalt in powder form or in the form of thin layers have less thermal stability. The properties of these materials can vary from soft to hard magnetic. Iron-cobalt and iron-nickel alloys are likewise magnetically soft and easily combustible. Another example of a combustible, but at the same time extremely hard magnetic material is the samarium-balt compound (SmCo ₅ ).

The magnetic properties of easily combustible magnetic materials even at low temperatures are either completely lost or change in a very characteristic way. In contrast, the magnetic properties of thermostable magnetic substances remain unchanged.

If valuable documents are documents of the same type, but have a different value in each case, for example, they are banknotes of different denominations, then it is preferable to provide such documents of the same value or denomination with different pairs of properties as signs of authenticity, so when checking the residues from combustion can be classified not only by the “genuine” or “fake”, but also by a specific category, for example, give an opinion on the value of a valuable document. The existence of such an opportunity is advisable primarily in the case of banknotes, since it is often impossible to determine from the combustion residues which denomination the banknotes originally had, and their owner needs confirmation that this ash is left from banknotes of a certain denomination.

You can introduce or introduce substances designed to protect documents from counterfeiting in various ways. If a valuable document is made of paper or has a paper layer, then such substances can be uniformly mixed into the paper pulp during the paper-making process or sprayed or imprinted on certain sections of the finished but still wet paper web, or otherwise applied to this web or embed in it.

If a valuable document is made of plastic or a polymeric material, then substances intended to be protected against counterfeiting can be added to the composition of this plastic or polymeric material at the stage of its manufacture and then processed together into films or fibers. After that, such films or fibers can be used to produce directly a valuable document or in the manufacture of a valuable document. At the same time, it is also possible to embed a paper cut into, for example, a film cut into narrow strips, as protective threads, for example. Another possibility is to supply melange fibers or plates intended for protection against counterfeiting. In this case, similarly to protective threads, the substances intended for protection against counterfeiting can either be introduced directly into the material of these melange fibers or plates, or printed on their surface, or mixed with the dye solution used to color them.

Another possibility is to use polymer films as cover films used to laminate identity cards or passports.

In another embodiment, a valuable document can also be sealed with printing ink, which includes one or more substances intended to protect against counterfeiting. In addition, similar substances can be found in various printing inks. In this case, any printing method can be used, in particular gravure printing, thermal transfer printing, hot stamping, screen printing.

Other possible embodiments of the invention are briefly discussed in the following examples.

Example 1

Two phosphors with different emission spectra are mixed into the paper pulp for the manufacture of paper protected from counterfeit paper before forming the web from it. Moreover, according to the invention, Y ₃ Al ₅ O ₁₂ : Tb with a very characteristic emission in the green region of the spectrum is used as a thermostable phosphor. As a less stable phosphor, the ZnS: CuCl compound is used, the radiation of which also lies in the green region of the spectrum, but disappears even at temperatures of about 700 ° C. Despite the fact that the radiations of both of these phosphors lie in the green region of the spectrum, these radiations have such a different spectral distribution that they can be detected using measuring equipment separately from each other.

If you burn the finished paper and allow it to burn under normal atmospheric conditions, then both phosphors can be found in the ashes. Only when burning paper in a flame furnace at temperatures above 1000 ° C is the destruction of a less thermostable phosphor ZnS. In contrast, the inorganic phosphor doped with terbium, withstands the effects of such temperatures and retains its properties, due to which ash can be identified as the remainder of the original document _{on the} basis of the emission spectrum characteristic of Y ₃ Al ₅ O ₁₂ : Tb, which also confirms the formation of this ash in conditions other than normal atmospheric conditions.

Example 2

Two phosphors with different emission spectra are mixed into the printing ink. As thermostable phosphor, manganese-doped zinc silicate (product CD 112 from Allied Signal) with radiation in the green region of the spectrum is used. As a less stable phosphor, a chelate compound europium from the class of tenoyl trifluoroacetonates (product CD 335 from Allied Signal) is used, the fluorescence of which lies in the red region of the spectrum.

When applying paint to any base, the colors of both fluorescent pigments are visually perceived as mixed. If such a base is then subjected in a flame furnace to temperatures exceeding 800 ° C, then the chelate compound europium will be destroyed. In contrast, an inorganic phosphor can withstand the effects of these temperatures and retains its properties, so that, based on the characteristic fluorescence spectrum, the ash can be identified as the remainder of the original document. At the same time, there is also the opportunity to confirm the formation of this ash under conditions different from normal atmospheric conditions.

Example 3

A synthetic resin obtained, for example, by polyaddition of multifunctional isocyanates, melamine and benzamide, is mixed with europium doped yttrium oxide (product CD 106 from Allied Signal) as an inorganic phosphor together with an organic phosphor from the benzothiazole class (product CD 333 from Allied Signal) with fluorescence emission in the yellow-green region of the spectrum. In this way, a substance in the form of a powder intended for protection against counterfeiting is obtained, which, when excited by UV radiation, is characterized by orange fluorescence. If the luminescent pigment obtained in this way is added to the printing ink and applied to the paper, the result will be orange fluorescence. If this paper is then subjected in a flame furnace to temperatures exceeding 800 ° C, the organic phosphor will be destroyed. In contrast, an inorganic phosphor can withstand the effects of these temperatures and retains its properties, so that, based on the characteristic fluorescence spectrum, the ash can be identified as the remainder of the original document. In this case, it is also possible to confirm the formation of this ash under conditions different from normal atmospheric conditions. In this case, the ash is characterized by red fluorescence.

Example 4

Manganese and lead-doped calcium silicate (product CD 110 from Allied Signal) with orange fluorescence is mixed as an inorganic fluorescent pigment to one of two different offset inks, and anthranilic acid-based organic pigment (product CD 329 from Allied Signal is mixed with the other offset ink) ) with blue fluorescence. Inks obtained in this way are alternately applied in the form of an encoding marking to a film, which is then cut into narrow strips and used as protective threads in the manufacture of paper. If the security paper so labeled is then subjected in a flame furnace to temperatures exceeding 800 ° C, the organic phosphor will be destroyed. In contrast, an inorganic phosphor can withstand the effects of these temperatures and retains its properties, so that, based on the characteristic fluorescence spectrum, the ash can be identified as the remainder of the original document. At the same time, there is also the opportunity to confirm the formation of this ash under conditions different from normal atmospheric conditions. In this case, ash is characterized by orange fluorescence.

Example 5

In this case, the phosphors used in Example 4 are mixed, firstly, with printing ink, and secondly, with paper, as described in Example 1. After applying printing ink to paper made in this way, a document is obtained that is characterized by orange fluorescence in the print and blue fluorescence in paper. If the security paper so labeled is then subjected in a flame furnace to temperatures exceeding 800 ° C, the organic phosphor will be destroyed. In contrast, an inorganic phosphor can withstand the effects of these temperatures and retains its properties, so that, based on the characteristic fluorescence spectrum, the ash can be identified as the remainder of the original document. At the same time, there is also the opportunity to confirm the formation of this ash under conditions different from normal atmospheric conditions. In this case, ash is characterized by orange fluorescence.

Example 6

A printing ink for intaglio printing is obtained by applying a swab or screen printing with samarium-cobalt powder (SmCo ₅ ). In this case, 1 part of vinylite is added as a binder with 1-2 parts of a magnetic pigment and 0.5-3 parts of ethyl acetate as a solvent. The amount of solvent depends on the printing method used. If the ink is applied by intaglio printing, then a larger amount of solvent is required, and vice versa, when receiving ink for screen printing, a smaller amount of solvent is required.

A second printing ink of the above composition is obtained with carbonyl iron powder (99% Fe). Then both of these inks, if necessary with the addition of other pigments, are applied by printing in the form of a barcode on a polymer film, which is then cut into strips in the form of protective threads. These threads are completely embedded in the paper during its manufacture.

The combination of samarium-balt compound with carbonyl iron described above provides a high degree of protection against counterfeiting, since the combination of such compounds is not a commercially available product and exhibits very characteristic magnetic properties. A samarium-cobalt compound with a residual magnetization of about 40,000 Oe refers exclusively to hard magnetic materials, while the residual magnetization of carbonyl iron is only less than 10 Oe.

When a security burns under atmospheric conditions, the samarium-balt compound decomposes into completely non-magnetic oxides, and carbonyl iron turns into iron oxides Fe ₂ O ₃ and Fe ₃ O ₄ with a significantly higher remanence compared to carbonyl iron in the range of about 200 to 400 Oe .

Thus, the magnetically hard properties as a result of combustion are lost, and the soft magnetic properties are preserved, although they change somewhat.

Example 7

The magnetic pigments described in Example 6, i.e. the samarium-cobalt compound and carbonyl iron can also be mixed with inks for offset printing, letterpress or steel printing. To this end, from 0.3 to 1 part of magnetic pigment and 1 part of linseed oil are mixed. At the same time, depending on the printing method, drying oil is ground with more or less linseed oil to obtain a correspondingly thinner mass (for offset printing) or thicker mass (printing from steel engravings).

Using this printing ink, the security paper is sealed with various signs or patterns in one area or in different areas.

The analysis of charred or burnt material, which previously was supposedly a valuable document proposed in the invention, is carried out on the basis of automatically controlled physical or chemical properties of the substance used to protect against counterfeiting. In this case, the information about the controlled property is automatically processed and compared with the reference or control values stored in the memory. If the valuable document was supposedly erroneously burned under atmospheric conditions, then the measured values of the controlled property are compared with the expected reference values for the temperature range above about 400-500 ° C and below about 1000 ° C. An unambiguous conclusion that we are talking about a genuine valuable document is possible only if the measured values coincide with the reference values.

At the same time, it can also be established whether the alleged valuable document really burned out under atmospheric conditions. The coincidence of the measured values with the reference values for the range of destruction temperatures exceeding approximately 1000 ° C may indicate that the ash was unauthorized removed from the process of destruction of securities and declared as residues of the erroneously burned valuable document in order to exchange these residues for an undamaged valuable document at the issuing institution.

In order to increase the reliability of ash identification for the detection of materials intended to protect against counterfeiting, respectively, of the characteristic components of these materials and to determine their concentration, trace analysis methods can be used. Suitable for this are, for example, methods such as atomic absorption spectroscopy (AAS), atomic emission spectroscopy (AES) in the discharge spectrum, and electron beam x-ray emission spectroscopy (ERES).

These methods of trace analysis allow you to identify primarily those intended to protect against counterfeiting substances that are not contained in the ashes of documents that are not protected by the proposed invention. Moreover, in the above example 1, the presence of elements such as yttrium, terbium, zinc and copper, as well as the concentration ratio of these elements, is determined. At the same time, in example 7, the presence of iron, cobalt and samarium is determined, and the concentration ratio of these elements is also evaluated.

Claims (29)

1. A valuable document, primarily a banknote or an identification card, characterized by the presence of at least two phosphors, the luminescent properties of which can be automatically controlled independently of each other, while the first phosphor irreversibly loses its luminescent properties at the first temperature, and the second phosphor is irreversibly loses its luminescent properties at a second temperature, characterized in that the first and / or second temperature exceeds its own burning temperature of a valuable document. 2. The valuable document according to claim 1, characterized in that the first temperature is less than or equal to the intrinsic temperature of the value document, and the second temperature exceeds the intrinsic temperature of the value document. 3. Valuable document according to claim 1 or 2, characterized in that the first and / or second temperature exceeds its own burning temperature of the valuable document, but less than the temperature of destruction of the valuable document. 4. Valuable document according to any one of claims 1 to 3, characterized in that the second temperature exceeds the temperature of destruction of the valuable document. 5. Valuable document according to any one of claims 1 to 4, characterized in that the luminescent properties of the phosphors can be automatically controlled in the same place, but independently of each other. 6. Valuable document according to any one of claims 1 to 5, characterized in that the intrinsic burning temperature of the valuable document is 400 - 600 ° C, preferably about 500 ° C. 7. Valuable document according to any one of claims 1 to 6, characterized in that the temperature of destruction of the valuable document is at least 1000 ° C. 8. Valuable document according to any one of claims 1 to 7, characterized in that the first phosphor is an inorganic phosphor, and the second phosphor is an organic phosphor. 9. The valuable document of claim 8, wherein the organic phosphor is methylene blue. 10. Valuable document according to any one of claims 1 to 7, characterized in that the first and second phosphors are in each case inorganic phosphors. 11. Valuable document according to any one of claims 8 to 10, characterized in that the inorganic phosphors contain crystalline substances in the matrix lattice of which dopants of rare-earth elements are present. 12. Valuable document according to any one of claims 1 to 11, characterized in that at least one of the luminescent properties is present on or in the protective threads or melange fibers. 13. Valuable document according to any one of claims 1 to 12, characterized in that at least one of the luminescent properties is present in at least one printing ink, which printed a valuable document. 14. Valuable document according to any one of claims 1 to 13, characterized in that at least one of the luminescent properties is present in the base material of the valuable document. 15. Valuable document according to any one of claims 1 to 14, characterized in that the base material of the valuable document is mainly paper, preferably cotton fiber paper. 16. A valuable document according to any one of claims 1 to 14, characterized in that the base material of the valuable document is mainly plastic or polymeric material. 17. A combination of substances to protect valuable documents from counterfeiting, consisting of at least two phosphors, the luminescent properties of which can be automatically controlled independently of each other, while the first phosphor irreversibly loses its luminescent properties at the first temperature, and the second phosphor is irreversibly loses its luminescent properties at a second temperature, characterized in that the first and / or second temperature exceeds its own burning temperature of a valuable document. 18. The combination of substances according to 17, characterized in that the first phosphor is an inorganic phosphor, and the second phosphor is an organic phosphor. 19. The combination of substances according to p. 18, characterized in that the organic phosphor is methylene blue. 20. The combination of substances according to p. 18, characterized in that the first and second phosphors are in each case inorganic phosphors. 21. The combination of substances according to any one of claims 18 to 20, characterized in that the inorganic phosphors contain crystalline substances in the matrix lattice of which dopants of rare-earth elements are present. 22. The combination of substances according to item 21, characterized in that the rare earth element is selected from the group comprising neodymium, ytterbium, praseodymium, erbium and holmium. 23. The combination of substances according to item 21 or 22, characterized in that the matrix lattice contains elements selected from the group comprising chromium and iron. 24. The combination of substances according to claim 20, characterized in that the second phosphor is ZNS: CuCL, and the first phosphor is Y ₃ AL ₅ O ₁₂ : Tb. 25. A method of manufacturing valuable documents according to any one of claims 1 to 16, which consists in the fact that the valuable document is supplied with the first and second phosphors inextricably linked with it. 26. The method according A.25, characterized in that at least one of the phosphors is introduced or embedded as an additive in a protective thread, melange fibers or in the material of the most valuable document. 27. The method according A.25, characterized in that at least one of the phosphors is mixed with printing ink, which seals a valuable document. 28. The method according to any one of paragraphs.25-27, characterized in that the first and second phosphors are processed into a mixture thereof. 29. A method for checking charred or burnt material, which previously was supposedly a valuable document according to any one of claims 1-16, characterized in that the luminescent properties are checked, from the memory depending on the temperature to which the valuable document was exposed, the stored reference or control values, these reference or control values are compared with the measured values and determine whether the temperature at which the valuable document was charred or burned was intrinsic the temperature of its burning or the temperature of its destruction.