EA038855B1 - Method of double-probe analysis of complex substances - Google Patents

Description

The invention relates to nuclear geophysical methods for the analysis of complex substances. It can be used to determine the density and effective atomic number of various rocks and ores in the mining, metallurgical and other industries.

The selective gamma-gamma method is widely known, which consists in irradiating complex substances with gamma radiation and registering gamma radiation scattered by the substance (Gamma methods in ore geology, edited by A.P. Ochkur. Leningrad: Nedra, 1976, p. 91 ). This method has found wide application for assessing the material composition of various ores by the effective atomic number. The disadvantage of this method is a significant error in the determination of complex substances in conditions of variable density.

Also known is the density gamma-gamma method based on irradiation of complex substances with high-energy gamma radiation and registration of scattered matter gamma radiation (Pak YN, Pak D.Yu. Nuclear technologies in geophysical research. Textbook. Karaganda. Publishing house of KSTU , 2016 .-- 346 p.). The disadvantage of this method is its low sensitivity to density and dependence on the variability of the material composition, in particular the effective atomic number of a complex substance.

The closest in technical essence and the achieved result is a method for the separate determination of the density and effective atomic number of complex substances, based on the irradiation of the substance with high-energy gamma radiation and the registration of scattered gamma radiation with two probes that record mainly single-scattered gamma radiation (small probe) and repeatedly scattered gamma radiation (large probe) (Innovative patent of the Republic of Kazakhstan No. 28371. Method for analyzing the composition of a substance. Authors: Pak Yu.N., Pak D.Yu., Imanov MO and others. Registered in the State Register of Inventions of the Republic of Kazakhstan 19.03 .2014).

The disadvantage of this method is the relatively low sensitivity to the effective atomic number and density in conditions of significant variability of the material composition.

The objective of the invention is to increase the sensitivity of determining the effective atomic number and density in a wide range of their changes.

The technical result of the invention is to expand the scope of the method.

The task is solved in the following way.

In the process of irradiation of a complex substance with high-energy gamma radiation and registration of scattered gamma radiation by two probes, in addition, on standard samples of the substance with average values of the effective atomic number, the intensities of scattered gamma radiation are measured depending on its energy at a small probe length L and a large probe length L2, find critical energies E ₁ and E ₂ , corresponding to the maximum in the spectrum of scattered gamma radiation, in the region above E1, find the energy interval AE1, at which the minimum sensitivity to the effective atomic number is achieved, in the region below E2, find the energy interval AE2, at which the maximum sensitivity to effective number, on the investigated substance of complex composition is measured: with a small probe length, the intensity of scattered gamma radiation N1 in the found energy interval AE1, with a long probe length, the intensity of scattered gamma radiation N2 in the found energy interval ale AE2, the density of the complex substance is determined from the measured intensity N1, and the effective atomic number of the complex substance is determined from the ratio of the measured intensities N2 / N1.

Experimental studies of the regularities of changes in the energy distribution of scattered gamma radiation depending on the length of the probe (distance from the gamma radiation source to the detector) and the effective atomic number of a complex substance have established that the critical energy corresponding to the maximum in the spectrum of scattered gamma radiation depends in a complex way on the length of the probe and the test substance. With a short probe length, predominantly single-scattered gamma radiation enters the detector. With a long probe length, the detector predominantly detects multiply scattered gamma radiation. Therefore, in the spectral distribution of scattered gamma radiation measured at a short probe length, the value of the critical energy is higher than in the case of a long probe length. Such a shift in the critical energy is quite natural.

Studies have also revealed a regular shift in the critical energy when the effective atomic number of the analyte changes, which is explained by competing processes of interaction of gamma radiation, in particular, the probability of photoelectric absorption of gamma radiation increases with the growth of the substance and is inversely proportional to the energy of gamma radiation, and the probability of Compton scattering of gamma radiation, prevailing at high energies, is proportional to the density of the substance and weakly depends on the substance. These circumstances are used to increase the sensitivity to the effective atomic number and density of the substance. The critical energy (maximum of the energy distribution of scattered gamma radiation) shifts to the region of lower energies with an increase in the effective atomic number of the substance and its density. A similar shift in the critical energy occurs when passing from measurements with a small probe to measurements with a large probe.

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With a small probe length (no more than the mean free path of primary gamma radiation), the energy interval ΔΕ1 found in the region above E1, from the point of view of the minimum sensitivity to matter, makes it possible to increase the sensitivity to density and minimize the effect of variable material composition.

With a large probe length (at least three free path lengths of primary gamma radiation), the energy interval ΔΕ ₂ found in the region below E ₂ , from the point of view of maximum sensitivity to matter, makes it possible to increase the sensitivity to the effective atomic number and minimize the effect of variable density due to normalization measured intensities (ratio of intensities N2 / N1).

The intensity of the scattered gamma radiation N1 in the found energy interval ΔΕ ₁ (over the inversion region of the spectral distribution), measured at a short probe length L1, and the intensity of the scattered gamma radiation N2 in the found energy interval ΔΕ ₂ (pre-inversion region of the spectral distribution), measured at a large length probe L2, are key informative parameters that increase the sensitivity to the effective atomic number and density of a substance in a wide range of their variation, which significantly expands the scope of the method.

A significant difference between the invention and the prototype is that, in addition, on standard samples of a substance with average values of the effective atomic number, the intensity of scattered gamma radiation is measured depending on its energy with a short probe length L ₁ and a large probe length L ₂ , find the critical energies E ₁ and E ₂ , corresponding to the maximum in the spectrum of scattered gamma radiation, in the region above E1, find the energy interval ΔΕ ₁ , at which the minimum sensitivity to the effective atomic number is achieved, in the region below E _2, find the energy interval ΔΕ2, at which the maximum sensitivity to the effective number , on the investigated substance of complex composition is measured: with a small length of the probe, the intensity of scattered gamma radiation N1 in the found energy interval ΔΒ1, with a large length of the probe, the intensity of scattered gamma radiation N2 in the found energy interval ΔΕ2, the density of the complex substance is determined by the measured intensity N1, and the effective atomic number of the complex substance is determined from the ratio of the measured intensities N2 / N1.

Experimental testing of the method is carried out on the example of a two-probe study of barite ores. The cesium-137 radionuclide (660 keV) was chosen as the source of the primary gamma radiation. The bulk density of ores varied within 2.6-4.7 g / cm ³ . The effective atomic number varied from 14.2 to 24.8.

The optimal parameters of the collimated probe (the collimation angle of the detector, the height of the air gap between the probe and the ore surface) are selected from the point of view of the maximum differentiation of the energy spectra of scattered gamma radiation from the material composition of the ores. The length of the small probe is 8.5 cm, the length of the large probe is 29 cm. The optimal energy interval ΔΕ1, selected for a short probe length, was 50 keV, and the optimal energy interval ΔΕ2, selected for a large probe length, was 85 keV.

The table shows comparative data on the sensitivity of the proposed method and the prototype method.

Way Change range: g / cm ³ Sensitivity to effective atomic number percent / 1 g / cm ³ Sensitivity to density, percent / 1 g / cm ³ The proposed 15.5 11.4 Prototype 12.6 9.4

The proposed method for two-probe study of complex substances is characterized by increased sensitivity to the effective atomic number and density of the substance in a wide range of their variation, which significantly expands the scope of the method.

Claims (1)

CLAIM The method of two-probe study of complex substances, based on its irradiation with gamma radiation and registration of scattered gamma radiation with two probes, characterized in that additionally, on standard samples of a substance with average values of the effective atomic number, the intensity of scattered gamma radiation is measured depending on its energy at a short probe length L1 and a large probe length L2, find the critical energies E1 and E ₂ , corresponding to the maximum in the spectrum of scattered gamma radiation, in the region above E1 find the energy interval AE1, at which the minimum sensitivity to the effective atomic number is achieved, in the region below E ₂ find the energy interval ΔΕ2, that maximizes the sensitivity to an effective number to the test substance complex composition measured: the short length of the probe 2 038 855 invariant intensity of scattered gamma radiation results in Nj AE energy interval _L at a high intensity probe length rasseyannog about gamma radiation N ₂ in the found energy range AE ₂ , the density of the complex substance is determined from the measured intensity Nj, and the effective atomic number of the complex substance is determined from the ratio of the measured intensities Ν ₂ / ι.