EA005903B1 - Method of identification and protection of excise stamps, banknotes, securities, documents and items and carrier of latent image as identification and protection mark - Google Patents

Abstract

The invention relates to creating latent images and inscriptions on the surface of items, in particular, excise and identification stamps, banknotes, securities and documents, forms of strict keeping, marks of conformity goods and articles. The invention permits to raise the protection from forgery and reduce the consumption of expensive materials. A method of identification and protection excise stamps, banknotes, securities, documents and different other articles comprises applying on the article surface areas of protection coating from luminescent composition being strontium aluminate in the lattice of which present simultaneously ytterbium and erbium atoms, and subsequent irradiation of said areas by ultra-violate and infra-red radiation recording anti-stokes luminescent radiation with naked eye. The carrier of latent image comprises applied on the article surface areas of protection coating from luminescent composition being strontium aluminate in the lattice of which present simultaneously ytterium, erbium and thulium atoms.

Description

The invention relates to the field of creating hidden drawings and inscriptions on the surface of products, in particular, excise and identification marks, banknotes, securities and documents, forms of strict accountability, marks of conformity of goods and products.

A known method of identification and protection and the carrier image (patent I8 No. 4930438). In this method and device using electromagnetic or electrostatic latent images deposited on the surface of the product, or images from phosphors irradiated in the ultraviolet region. These materials, in particular phosphors, are simple substances and can be easily prepared in any chemical laboratory. More than 5000 ultraviolet phosphors are known, which allows a specific luminescence to either pick up from a variety of similar, sometimes differing only in intensity of luminescence, or to simulate the effect by adding several phosphors.

Increasing the degree of protection against image falsification, increasing the chemical stability of the image and simplifying the method of creating and developing an image is achieved in patent number 2137612. This method of identification and protection and the carrier of the latent image are closest to the proposed one. The protective coating in the form of plots of size and shape is made of an anti-Stokes luminescent compound or includes an anti-Stokes luminescent compound, which is a crystalline structure, in the lattice of which there are at the same time atoms of several rare-earth metals, and irradiation is produced by infrared radiation.

The indicated method of identification and protection and the carrier of the image are realized through the use of an invisible compound consisting of several, as a rule, at least three rare earth metals, the so-called anti-Stokes compounds. The property of these compounds is that when excited by radiation in the infrared region, they emit light in the visible part of the spectrum with a frequency many times higher than the frequency of the exciting radiation.

This method complicates the possibility of faking a latent image, but does not completely exclude this possibility, since the selection of anti-Stokes luminescent compounds with emission at the required wavelength, despite the inaccessibility of the materials used, is fundamentally possible.

The technical objective of this invention is to further increase the degree of protection against forgery of the image and reducing the consumption of expensive materials.

The task according to the first aspect of the invention is solved by a method of identifying and protecting excise stamps, banknotes, securities, documents and products, including applying a protective coating to the surface of an article with an anti-Stokes luminescent compound, and irradiating the coating with infrared radiation, while the anti-Stokes luminescent compound has a crystalline a structure in the lattice of which there are at the same time atoms of several rare-earth elements in which, according to the invention, they use a luminescent compound in the form of a fine powder, the crystal structure is strontium aluminate, in the lattice of which there are atoms of at least yttrium, erbium and thulium, and before irradiation of the coating by infrared radiation, it is irradiated with ultraviolet radiation.

Preferably, at least one area of protective coating specified in size and shape is applied to the surface of the product.

It is advisable that the protective coating consists entirely of anti-Stokes luminescent compound.

It is desirable to carry out the irradiation of the protective coating by infrared irradiation with a wavelength of 960 nm.

It is possible to carry out the irradiation of the protective coating with ultraviolet radiation with a wavelength of 365 nm.

It is advisable to use a fluorescent compound in the form of a fine crystalline powder in the metal, or resin, or plastic, or rubber, or glass.

Preferably, the fine powder has a particle size of up to 30 microns.

It is desirable that the radiation of a mercury source be used as ultraviolet radiation.

It is possible that the radiation of a gallium arsenide LED is used as infrared radiation.

The task according to the second aspect of the invention is solved by means of a latent image carrier comprising a protective coating applied to the product surface with an anti-Stokes luminescent compound having a crystalline structure, in the lattice of which there are simultaneously atoms of several rare-earth elements, in which, according to the invention, the luminescent compound is applied in the form fine powder, the crystal structure is strontium aluminate, in the lattice of which there are ohms, at least yttrium, erbium and thulium.

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Preferably, at least one protective coating area is applied to the surface of the product.

It is advisable that the protective coating consists entirely of anti-Stokes luminescent compound.

It is desirable that the protective coating was made in the form of fine crystalline powder in the metal, or resin, or plastic, or rubber, or glass.

It is possible that the fine powder had a particle size of up to 30 microns.

The protective material is an anti-Stokes compound, which is a fine crystalline powder of strontium aluminate (8A1 ₂ O ₄ ), in the structure of which there are several rare-earth elements, including Υ, Er, Ti, capable of excitation and weak luminescence when exposed to infrared radiation (960 nm) .

The concentration of rare-earth elements in the crystal matrix is selected depending on the power of the detecting equipment in such a way that under the influence of infrared radiation there is a weak and not visually detectable luminescence.

Preliminary excitation of a compound by an ultraviolet radiation source (365 nm) sensitizes the compound, resulting in a luminescent glow, enhanced by Υ, Er, Ti in the 540 nm region (green glow) upon further irradiation with infrared radiation, and its registration with the naked eye is possible.

The ratio of rare earth elements is approximately 80%, 15% Er and 5% Ti.

Considering that the degree of purity of rare earth elements used in this invention must be very high (99.99%), which leads to their high cost, reducing the concentration of these materials while ensuring the possibility of visual observation of their luminescence is a very important aspect.

The coating can be applied to the protected surface either directly in the form of a powder, or by printing or other means (for example, as part of paint, glue, ink, etc.).

The label obtained using such a protective material is detected (highlighted) by a simple detector that has the dimensions of a conventional pen emitting invisible IR rays. The detector consists of a LED made on the basis of gallium arsenide, and a miniature power source (batteries). Pre-irradiation with ultraviolet radiation is produced by a compact mercury source.

The proposed protective material is extremely chemical resistant to aggressive media. Tests were carried out by boiling in concentrated and diluted acids: sulfuric, hydrochloric and nitric (separately); in alkaline melt, as well as heating in the presence of oxygen to 1000 ° C. In all cases, the anti-Stokes compound has retained its properties.

Claims (14)

CLAIM 1. A method of protecting and identifying excise stamps, banknotes, securities, documents and products, including applying a protective coating with an anti-Stokes luminescent compound to the surface of the product and irradiating this coating with infrared radiation, while the anti-Stokes luminescent compound has a crystal structure, in the lattice of which are simultaneously atoms of several rare-earth elements, characterized in that fine-dispersed strontium aluminate powder is used as a luminescent compound, eshetke crystal structure with atoms of at least yttrium, erbium and thulium, wherein before irradiation with infrared radiation on the coating layer to the ultraviolet light. 2. The method according to claim 1, characterized in that at least one predetermined size and shape of the protective coating is applied to the surface of the product. 3. The method according to any one of claims 1 or 2, characterized in that the protective coating consists entirely of anti-Stokes luminescent compound. 4. The method according to any one of claims 1 to 3, characterized in that the protective coating is irradiated with infrared radiation with a wavelength of 960 nm. 5. The method according to any one of claims 1 to 4, characterized in that the protective coating is irradiated with ultraviolet radiation with a wavelength of 365 nm. 6. The method according to any one of claims 1 to 5, characterized in that a protective coating is used with a luminescent compound in the form of a fine crystalline powder in a metal or resin, or plastic, or rubber, or glass. 7. The method according to any one of claims 1 to 6, characterized in that the fine powder has a particle size of up to 30 microns. 8. The method according to any one of claims 1 to 7, characterized in that a mercury lamp is used as a source of ultraviolet radiation. 9. The method according to any one of claims 1 to 8, characterized in that a gallium arsenide LED is used as the source of infrared radiation. - 2 005903 10. A latent image carrier containing a protective coating applied to its surface with an anti-Stokes luminescent compound, characterized in that the luminescent compound is a fine powder of strontium aluminate, in the lattice of the crystal structure of which there are atoms of at least yttrium, erbium and thulium. 11. The carrier according to claim 10, characterized in that at least one protective coating portion specified in size and shape is applied to its surface. 12. The carrier according to any one of paragraphs.10 or 11, characterized in that the protective coating consists entirely of anti-Stokes fluorescent compounds. 13. The carrier according to any one of paragraphs.10-12, characterized in that the protective coating is made in the form of fine crystalline powder in metal, or resin, or plastic, or rubber, or glass. 14. The carrier according to any one of paragraphs.10-13, characterized in that the fine powder has a particle size of up to 30 microns.