RU2068199C1 - Method for labeling and radiation checking of objects - Google Patents

Abstract

FIELD: methods for radiation detection. SUBSTANCE: method involves application of label, which contains luminescent material with individual set of components, to object to be checked, exposing of applied label to stimulating radiation, recording characteristics of luminescent illumination, subsequent exposing of applied label to stimulating radiation for each checking operation, comparison of detected characteristics against recorded characteristics. Specific feature of method is random selection of luminescent components with different duration of luminescent illumination as individual sets of components for labels. Label is exposed to radiation pulses which duration is less than luminescent illumination of any luminescent component in set. Duration of luminescence is used as recorded characteristic. EFFECT: increased precision of identification of objects in series of similar objects. 2 cl

Description

 The invention relates to methods for recording radiation and can be used for marking various objects and their subsequent control.

 A known method of marking products, which consists in applying to the surface of the object a material that differs in physical properties from the material of the object, in particular, an alloy of metals whose chemical composition corresponds to the given information (USSR author's certificate N 1096690 class G 06 K 1/12, published. 1984). The disadvantage of this method is the limited application.

 Closest to the claimed one is a method for marking and radiation monitoring of objects, which includes applying an identification mark on the basis of a luminescent substance to the controlled object with an individual set of ingredients, irradiating the applied identification mark with stimulating radiation, recording luminescence radiation parameters, re-irradiating the identification mark with stimulating radiation during each operation control and comparison of the luminescent emission parameters recorded in this case relations with previously registered parameters (UK application N 2062221 CL G 01 N 23/223, published. 1981).

 The disadvantage of this method is the inability to accurately distinguish between individual objects, because a set of ingredients is selected for a whole group of controlled objects, in particular, for paper banknotes.

 The proposed method, unlike the prototype, allows for individual control of objects. The method consists in the fact that an identification mark containing luminescent substances is applied to the object, irradiated with “stimulating” radiation, luminescence radiation is recorded, which is used to recognize the object, and characterized in that for each object, an identification mark substance having luminescent ingredients with with different times of exposure, irradiation is carried out by pulsed radiation with a duration shorter than the duration of the luminescent ingredients, and as a code about ekta use duration of the luminescence radiation.

The duration of luminescence emission for different phosphors is different
from several nm. for organic scintillators up to several hundred seconds for crystalline phosphors based on ZnS and CdS. By composing mixtures of various phosphors, you can get an almost unlimited number of identification marks, the kinetics of which will be different. As the code of the object, which is used to identify the object, determine the pulse duration at the output of the photoelectric detector, which registers the radiation of the identification mark at a given registration threshold.

 In order to reduce the likelihood of counterfeiting, several time intervals of pulse durations at the output of the detector are used as an object code at various detection thresholds. Thus, after one pulse of stimulating radiation, several time intervals are recorded, which are the code of this object. Since the glow of various ingredients has a different duration, the pulse at the output of the detector has a complex shape. The shape of the pulse depends on the ratio of the quantities of the various ingredients in the mixture.

 The quantities of ingredients are randomly selected. The probability of obtaining the same mixtures and, therefore, the same codes is almost zero.

Crystallophosphors based on zinc and cadmium sulfides, as well as calcium tungstates and others (CD ₂ O ₃ Tb, Y ₂ O ₂ Tb, ZnS-CdS-Ag, CsI Tl, CaWO ₄ , Ba, widely used in X-ray technology, are used as luminescent ingredients. ₃ (PO ₄ ) ₂ Eu, LaOB ₂ Tl, Yb) with a luminescence duration from 10 ^-7 to 10 ² s.

 An identification mark is applied to the surface of the controlled object in the form of an emulsion layer based on varnishes or epoxies with crystallophosphors introduced into them. The emulsion hardens and forms the identification mark of an object, for example, a painting.

 Identification marks applied to securities or watercolor paintings contain aqueous and alcoholic solutions of organic and inorganic scintillators that are widely used in physical experiments, for example, CsL-Tl, PPO, and POPOP solutions.

Claims (2)

 1. A method for marking and radiation monitoring of objects, including the application of an identification mark on the basis of a luminescent substance with an individual set of ingredients, irradiation of the applied identification mark with stimulating radiation, registration of luminescence emission parameters, repeated irradiation of the identification mark with stimulating radiation during each control operation and comparison of the luminescence emission parameters recorded in this case with previously recorded etrami, characterized in that the individual sets of markings ingredients administered random number luminescent ingredients with different durations of emission of luminescence radiation marking plate by radiation pulses of a duration shorter than the duration of luminescence radiation of any luminescent ingredient as well as the recorded parameters selected duration of luminescence radiation.  2. The method according to p. 1, characterized in that the duration of the luminescence radiation is recorded using a photoelectric detector with at least one predetermined detection threshold.