EA039341B1 - Method of x-ray fluorescence analysis of coal - Google Patents

Abstract

The invention relates to physical methods for analysis of substances. A method of X-ray radiometric analysis of coal, based on the measurement of the spectral ratio of the intensity of fluorescence measurement of iron to the intensity of scattered gamma radiation is characterized in that coal is additionally irradiated with gamma radiation with energy below the iron absorption K-edge, and, on standard samples with known content of pyrite, energy intervals E1 are detected in the region of X-ray fluorescence of sulfur and E2 in the region of scattered gamma radiation, which provide, respectively, maximum sensitivity of the intensity of fluorescence radiation of sulfur to pyrite and maximum sensitivity of the ratio f of the intensity of fluorescence radiation of sulfur at E1 to the intensity of scattered gamma radiation at E2, and pyrite content is determined by the spectral ratio together with the measured ratio f of the intensity of fluorescence radiation of sulfur at E1 to the intensity of scattered gamma radiation at E2. The technical result of the invention consists in improved accuracy and expanded scope of application of the method by detecting E1 and E2, at which the ratio of the intensities of f is measured.

Description

The invention relates to the field of analysis of various complex substances by nuclear physics methods and can be used to determine pyrite in coal during its mining and processing in the coal mining and fuel and energy industries.

A known method for determining the content of pyrite (FeS2), based on the irradiation of coal with gamma radiation and the registration of x-ray fluorescent radiation of iron (X-ray radiometric method in prospecting and exploration of ore deposits. Edited by A.P. Ochkur. L .: Nedra, 1985, p. 256) .

The disadvantage of this method is the relatively low accuracy due to the destabilizing effect of the matrix effect caused by the redistribution of the elemental composition of coal.

The closest in technical essence and the achieved result is a method consisting in registration along with X-ray fluorescent radiation of iron and scattered gamma radiation. The method, known as the method of spectral relations, involves measuring the ratio of the intensity of the fluorescent radiation of iron to the intensity of the scattered gamma radiation (Leman E.P. X-ray radiometric method for sampling deposits of non-ferrous and rare metals. L .: Nedra, 1978. p. 232). This method is characterized by a somewhat increased sensitivity to iron. At the same time, the perturbing effect of the variability of the elemental composition of coal on the results of the analysis and the insufficient information content of the method, due to the lack of instrumental signals about sulfur, the mass fraction of which in pyrite is slightly more than 53%, remain.

The objective of the invention is to improve the accuracy of determining pyrite by using an informative signal about sulfur and taking into account the variability of the elemental composition of coal.

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

The problem is solved in the following way. When irradiating the analyzed coal with gamma radiation and measuring the spectral ratio Ψ of the intensity of the X-ray fluorescent measurement of iron to the intensity of the gamma radiation scattered by the coal, the coal is additionally irradiated with gamma radiation with an energy less than the energy of the K-absorption edge of iron (~ 7.1 keV), and on standard samples of coal with a known content of pyrite, the dependences of the intensity of the secondary radiation on its energy are established, the width of the energy interval AE ₁ is found in the region of the fluorescent radiation of sulfur (~ 2.3 keV), at which the maximum sensitivity of the intensity of the fluorescent radiation is achieved with a single change in the concentration of pyrite, and the optimal width of the energy interval AE2 in the region of scattered gamma radiation is chosen such that with a single change in the concentration of pyrite in coal, the maximum sensitivity of the value of the ratio f of the intensity of fluorescent radiation of sulfur, measured with the found width of the interval ΔΕ ₁ , to the intensity of scattered gamma radiation measured at the selected interval width AE2, and the pyrite content in coal is determined from the spectral ratio of intensities Ψ together with the measured ratio f of the intensity of fluorescent radiation of sulfur measured at the found interval width ΔΕ ₁ to the intensity of scattered gamma radiation radiation measured at the selected interval width AE2.

Additional irradiation of coal with gamma radiation with an energy below the K-edge absorption of iron (7.2 keV) is caused by the need to effectively excite the X-ray fluorescence of sulfur and measure the intensity of its fluorescent radiation (2.3 keV). The width of the energy interval ΔΕ ₁ in the region of fluorescent radiation of sulfur is found, at which the maximum sensitivity of the intensity of fluorescent radiation is achieved with a single change in the concentration of pyrite, and the width of the energy interval AE2 in the region of scattered gamma radiation is chosen such that with a single change in the concentration of pyrite in coal, the maximum is provided. the sensitivity of the ratio f of the intensity of fluorescent radiation of sulfur, measured at the found width of the interval AB ₁ to the intensity of scattered gamma radiation, measured at the selected interval width AE2.

Such an algorithm of successive actions makes it possible to correct the magnitude of the spectral ratio Ψ of the intensity of the fluorescent radiation of iron to the intensity of the scattered gamma radiation, taking into account an additional instrumental parameter, which is the ratio f of the intensity of the fluorescent radiation of sulfur, measured at the width of the interval AB ₁ , to the intensity of the scattered gamma radiation, measured at the width interval AE2. The measured intensity ratio f makes it possible to obtain additional information about sulfur, the mass fraction of which in pyrite is more than 53%, which increases the accuracy of determining pyrite in coal. In addition, when using primary gamma radiation with an energy below the K-absorption edge of iron (7.1 keV), the mineral composition of coal can be approximated by a two-component mixture of aluminosilicates and calcium. Variations in the elemental composition are automatically taken into account by the intensity ratio f.

The essential difference between the invention and the prototype is that the coal is additionally irradiated with gamma radiation with an energy below the K-absorption edge of iron, and on standard samples of coal with a known pyrite content, the dependences of the intensity of the secondary radiation on its energy are determined, the width of the energy interval AE ₁ is found in the region sulfur fluorescent radiation

- 1 039341 (-2.3 keV), at which the maximum sensitivity of the intensity of fluorescent radiation is achieved with a single change in the concentration of pyrite, and the optimal width of the energy interval LE ₂ in the region of scattered gamma radiation is chosen such that with a single change in the concentration of pyrite in coal, the maximum sensitivity of the value of the ratio f of the intensity of the fluorescent radiation of sulfur, measured at the found width of the interval LE _1? to the intensity of scattered gamma radiation measured at the selected interval width LE ₂ , and the pyrite content in coal is determined by the spectral ratio of intensities Ψ together with the measured ratio f of the intensity of fluorescent radiation of sulfur measured at the found interval width ΔΕ| to the intensity of the scattered gamma radiation, measured at the selected width of the interval LE ₂ .

The proposed method was tested on the example of determining pyrite in coal with its additional irradiation from a Fe-55 radioisotope source emitting gamma radiation with an energy of 5.9 keV, which is lower than the energy of the iron K absorption edge (7.1 keV). On standard samples of coal with a known pyrite content (0.4-2.5)%, the intensity of X-ray fluorescent sulfur radiation in the region of its analytical line (-2.3 keV) is measured, and the width of the energy interval ΔΕ| in the region of fluorescent radiation of sulfur, at which the maximum sensitivity of the intensity of fluorescent radiation is achieved with a single change in the concentration of pyrite in coal. The maximum sensitivity was achieved with the width of the energy interval ΔΕ!=1.05 keV, which is symmetric with respect to 2.3 keV.

The optimal width of the energy interval ΔΕ ₂ in the region of scattered gamma radiation (-5.9 keV) is chosen such that with a single change in the concentration of pyrite in coal, the maximum sensitivity of the value of the ratio f of the intensity of fluorescent radiation of sulfur, measured with the found width ΔΕ! = 1, is provided, 05 keV to the intensity of the scattered gamma radiation measured at the selected width ΔΕ ₂ . The maximum sensitivity of the value of the ratio f was achieved at ΔΕ ₂ =2.85 keV, which is symmetrical with respect to 5.9 keV. With the found values of the energy intervals ΔΕ!=1.05 keV, ΔΕ ₂ =2.85 keV, the value of the ratio f of the measured intensities is measured, and the pyrite content in coal is determined by the value of the spectral ratio Ψ of the intensities together with the measured ratio f of the intensity of the fluorescent radiation of sulfur at the found width ΔΕ| to the intensity of the scattered gamma radiation at the selected width ΔΕ ₂ .

The table presents comparative experimental data on the sensitivity and error in the determination of pyrite in coals of variable material composition.

Way Number of samples Ca change range,% Root mean square error, % abs. Sensitivity to FeSz, percent / % abs. Proposed 24 0.4 - 3.2 0.49 4D4 Prototype 24 0.4 - 3.2 0.95 ZD6

The proposed method in comparison with the prototype compares favorably with increased sensitivity to pyrite and low error in the determination of pyrite under conditions of significant variability of the material composition, in particular calcium, which significantly expands the scope of its application.

CLAIM

Claims (1)

CLAIM A method for X-ray fluorescence analysis of coal based on its irradiation with gamma radiation and measuring the spectral ratio Ψ of the intensity of X-ray fluorescence measurement of iron to the intensity of gamma radiation scattered by coal, characterized in that the coal is additionally irradiated with gamma radiation with an energy less than the energy of the K-absorption edge of iron ( -7.1 keV), and on standard samples of coal with a known pyrite content, the dependences of the secondary radiation intensity on its energy are established, the width of the energy interval ΔΕ is found, in the region of sulfur fluorescent radiation (-2.3 keV), at which the maximum sensitivity of the intensity is achieved of fluorescent radiation with a single change in the concentration of pyrite, and the optimal width of the energy interval ΔΕ ₂ in the region of scattered gamma radiation is chosen such that with a single change in the concentration of pyrite in coal, the maximum sensitivity of the value of the ratio f of the intensity of fluorescence t radiation of sulfur, measured at the found width of the interval ΔΕ _1? to the intensity of scattered gamma radiation, measured at the selected interval width ΔΕ ₂ , and the pyrite content in coal is determined by the spectral ratio of intensities Ψ together with the measured ratio f of the intensity of sulfur fluorescent radiation, measured at the found interval width ΔΕ, to the intensity of scattered gamma radiation, measured at the selected interval width ΔΕ ₂ .