RU2137612C1 - Method for identifying and protecting excise labels, bank notes, securities, documents, and articles; cryptic image medium as identifying and protective mark - Google Patents

Abstract

FIELD: protection of various documents and articles against forgery. SUBSTANCE: method involves production and development of cryptic image that functions as identifying and protective mark. Identification medium has protective coating of anti-Stokes luminescent compound or includes anti-Stokes luminescent coating in the form of crystalline structure whose lattice incorporates atoms of several rare-earth metals at a time. EFFECT: improved reliability of forgery protection; improved image chemical stability; facilitated procedure. 9 cl

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, strict reporting forms, signs of conformity of goods and products.

 The traditional way to create and contour images is to apply thin layers of substances on the surface of the product that have a significant difference in optical properties (transmittance or reflection) from neighboring sections of the matrix. The latent (latent) image carrier is either special ink containing a special coloring component (for example, [1]). The manifestation of such images requires special solutions.

 Closest to the proposed method and device are the method of identification and protection and the image carrier according to [2]. 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. Over 5,000 ultraviolet phosphors are known, which allows a particular glow to be selected from many similar ones, sometimes differing only in the intensity of the glow, or to simulate the effect by adding several phosphors. In addition, these methods, in particular, a method for identifying and protecting phosphors operating in the ultraviolet region, require rather cumbersome stationary equipment powered by an electrical network. It should also be noted the high harmfulness to human health from exposure to ultraviolet rays reflected from the product.

 An object of the invention is to increase the degree of protection against falsification of the image, increase the chemical stability of the image and simplify the method of creating and developing the image by using simple methods of physical impact on the object.

 The problem is solved in that in the method of identification and protection of excise stamps, banknotes, securities, documents and products, including applying to the surface of the product specified in size and shape of the sections of the protective coating and irradiation of the sections with radiation, while the protective coating is made of anti-Stokes fluorescent compound or includes an anti-Stokes luminescent compound, which is a crystalline structure in the lattice of which are simultaneously atoms of several rare-earth materials, and irradiation is carried out by infrared radiation.

 In a particular case, yttrium and / or ytterbium and / or erbium and / or thulium are used as rare-earth materials.

 In this case, in particular, atoms of at least three rare-earth materials are simultaneously used.

 In a particular case, rare-earth atoms are used that are in a metal alloy, or resin, or plastic, or rubber, or glass.

 In this case, irradiation is carried out by infrared radiation of a gallium arsenide LED.

 The problem is also solved by the fact that in the image carrier, including the protective coating sections defined in shape and size, applied to the surface of the product, it 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 simultaneously several rare-earth atoms materials.

 As a rule, yttrium and / or ytterbium, and / or erbium, and / or thulium are used as rare-earth materials.

 In particular cases, atoms of at least three rare-earth materials are simultaneously used.

 In special cases, rare-earth atoms are used that are in a metal alloy, or resin, or plastic, or rubber, or glass.

 The proposed identification and protection method and image carrier are realized through the use of an invisible compound consisting of several, usually at least three, rare-earth metals, the so-called anti-Stokes compounds, or up-frequency transformers, or IR radiation counters, or IR radiation converters into visible light or frequency converters with energy transfer, or cooperative compounds. The property of these compounds is that when excited by radiation in the IR region, they emit light in the visible part of the spectrum with an intensity many times higher than the intensity of the exciting radiation.

 The proposed identification and protection method and the image carrier provide both a separate anti-Stokes compound emitting a specific color (for example, green, or blue, or red), as well as a complex protection that carries various combinations of two or three colors at the same time. Thus, it is possible to display two- or three-color complex geometric shapes, signs, inscriptions and drawings.

In this case, anti-Stokes luminescence also occurs when rare-earth materials are in a metal or other alloy (in resins, plastics, rubbers, glass, etc.)
Protective material - anti-Stokes compound consisting of several rare-earth metals is applied to the protected object by printing or in another way (as a part of ink, 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 infrared rays. The detector consists of an LED made on the basis of gallium arsenide, and a miniature power source (battery).

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

Sources of information
1. Patent US N 4889559, 12/26/1989.

 2. Patent US N 4930438, 06/05/1990.

Claims (9)

 1. The method of identification and protection of excise stamps, banknotes, securities, documents and products, including applying to the surface of the product specified in size and shape of the sections of the protective coating and irradiating the sections with radiation, characterized in that the protective coating is made of anti-Stokes fluorescent compound or includes anti-Stokes a luminescent compound, which is a crystalline structure, in the lattice of which are simultaneously atoms of several rare-earth materials, and irradiation is carried out by infrared radiation.  2. The method according to claim 1, characterized in that yttrium and / or ytterbium and / or erbium and / or thulium are used as rare-earth materials.  3. The method according to claim 1 or 2, characterized in that at the same time use atoms of at least three rare earth materials.  4. The method according to claims 1 to 3, characterized in that the atoms of rare-earth elements located in a metal alloy, or resin, or plastic, or rubber, or glass are used.  5. The method according to claim 4, characterized in that the irradiation is performed by infrared radiation of a gallium arsenide LED.  6. Carrier of the latent image, including the parts of the protective coating specified in shape and size applied to the surface of the product, characterized in that the protective coating 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 are simultaneously several rare-earth atoms materials.  7. The image carrier according to claim 6, characterized in that yttrium and / or ytterbium and / or erbium and / or thulium are used as rare-earth materials.  8. The image carrier according to claim 6 or 7, characterized in that the atoms of at least three rare earth materials are simultaneously used.  9. The image carrier according to any one of paragraphs.6-8, characterized in that the atoms of rare-earth elements located in a metal alloy, or resin, or plastic, or rubber, or glass.