EA038002B1 - Method for controlling quality of solid fuel - Google Patents

Abstract

The invention relates to physical methods for the analysis of substances. The disclosed is a method of controlling quality of solid fuel that consists in fuel exposure to gamma-ray radiation with a power below Fe absorption K edge and measurement of secondary radiation intensity, characterized in that standard fuel samples with minimum possible ash content and various calcium content in ash are used to additionally determine the dependence of secondary radiation intensity on the thickness of attenuating filter d, which is used to determine thickness d1 where an intensity is independent on calcium content in ash, while standard fuel samples with the maximum possible ash content and various calcium content in ash are used to determine the dependence of secondary radiation intensity on the thickness of attenuating filter, which is used to determine thickness d2 where intensity is independent on calcium content in ash, while the ash content is determined from the intensity of secondary radiation together with the ratio of intensities measured at d1 and d2. The technical effect of the invention consists in expansion of application scope and improvement of the ash content control accuracy due to additional measurement of secondary radiation intensities at the determined filter thicknesses.

Description

The invention relates to physical methods for analyzing complex substances, in particular, methods for controlling the quality of solid fuel using gamma radiation. It can be used for express analysis in the process of mining and processing of solid fuels in the mining, metallurgical and other industries.

There are widely known physical methods for controlling the quality of solid fuel based on scattering of gamma radiation (Starchik LP, Pak YN Nuclear-physical methods for controlling the quality of solid fuel. M. Nedra, 1985, 224 s).

The disadvantage of these known methods is a significant error in determining the quality (ash content), due to the variability of the elemental composition of the mineral part of the fuel, leading to the differentiation of the effective atomic number of the fuel not only from the ash content of the fuel but also the material composition of its mineral part, in particular iron and calcium.

The closest in technical essence and the achieved result is a method based on irradiating fuel with low-energy gamma radiation with an energy below the energy of the K-absorption edge of iron and registering a secondary radiation weakened by a filter of a certain thickness, including scattered gamma radiation and calcium fluorescent radiation. (Pak YN On the method of improving the accuracy of the analysis of ash content of coal. - Factory laboratory, 1980, No. 8, pp. 743-744).

This method almost completely eliminates the destabilizing effect of fluctuations in the content of the heaviest ash-forming element, which is iron. However, the influence of the inconstancy of the calcium content in the ash persists under conditions when the ash content of the fuel varies within significant limits. Therefore, the disadvantage of this method is its limited application and low accuracy in determining the quality of fuel in conditions when the ash content varies within significant limits.

The objective of the invention is to expand the scope of its application and improve the accuracy of the analysis under conditions of significant variability in the ash content of the fuel.

The technical result of the invention consists in expanding the scope and improving the accuracy of monitoring the ash content of the fuel under conditions of significant variability in both ash content and the material composition of the mineral mass, in particular the calcium content in the ash.

The task is solved in the following way.

The intensity of low-energy gamma-radiation scattered by the fuel depends on the effective atomic number of the fuel, which is closely dependent on the ash content and the material composition of the mineral (ash-forming) mass of the fuel. When using low-energy gamma radiation (less than the energy of the K-absorption edge of iron), calcium becomes the heaviest ash-forming element in terms of the photoelectric absorption coefficient. Therefore, when the ash composition (calcium content in ash) fluctuates, the intensity of the scattered gamma radiation will change and interfere with the analysis of solid fuels. Experimental studies on fuels of different ash content and different calcium content in ash have established qualitatively opposite patterns of changes in the intensities of scattered gamma radiation and fluorescent calcium radiation. This makes it possible to achieve a certain invariance of the results when the calcium content in ash fluctuates by measuring the integral intensity of secondary radiation, including gamma radiation scattered by the fuel (~ 5.9 keV) and calcium fluorescent radiation (~ 3.7 keV).

Artificial attenuation of secondary radiation by a filter made of light material, for example, polyethylene, expands the methodological capabilities of the method, which is due to the sharply different gamma-attenuating properties of the filter material in relation to scattered radiation (5.9 keV) and X-ray fluorescent radiation of calcium (~ 3.7 keV) and so that with a change in the calcium content in the ash, the increment in the intensity of the fluorescent radiation is higher than the increment in the intensity of the scattered radiation.

Complex regularities of the intensity of secondary radiation from the ash content of the fuel, the calcium content in the ash, and the thickness of the attenuating filter have been revealed. It was found that at a certain filter thickness, the intensity of the secondary radiation is independent of the calcium content in the ash.

For example, a filter with a thickness of 35 mg / cm ² is optimal from the point of view of insensitivity to variations in calcium for fuels with ash content in the range of 13-17%, and for high-ash fuel (32-37%) the optimal filter thickness is about 60 mg / cm ² . There is a clear pattern between the optimal thickness of the attenuating filter and the ash content of the fuel. This makes it possible to choose the dependence of the intensity of the secondary radiation attenuated by a filter of various thicknesses as a correcting parameter, from which the thickness d1 is found, at which the intensity of secondary radiation does not depend on the calcium content in the fuel with the lowest possible ash content, and on fuel with the maximum possible ash content and different contents calcium, the dependence of the secondary radiation intensity on the filter thickness is established, and the thickness d2 is found from it, at which the secondary radiation intensity does not depend on the calcium content in the ash.

The ratio of the intensities of secondary radiation, measured at the found thicknesses di and d ₂ , serves as an unambiguous indicator of the calcium content in ash in the range of ash content from the minimum to the maximum possible.

- 1 038002

A significant difference between the invention and the prototype is that, in addition, on standard fuel samples with the lowest possible ash content and different calcium content in the ash, the dependence of the intensity of secondary radiation on the thickness of the attenuating filter d is established, from which the thickness d1 is found, at which the intensity of secondary radiation does not depend on the content calcium in ash, and on standard fuel samples with the maximum possible ash content and different calcium content in ash, the dependence of the intensity of secondary radiation on the thickness of the attenuating filter is established, from which the thickness d _{2 is found} , at which the intensity of secondary radiation does not depend on the calcium content in the ash, and on solid fuel of unknown quality, the secondary radiation intensity is measured sequentially at the found filter thicknesses d1 and d2, and the ash content of the fuel is determined from the secondary radiation intensity together with the ratio of secondary radiation intensities measured at d1 and d ₂ .

An example of the implementation of the proposed experience.

The analyzed fuel sample is irradiated with gamma radiation with an energy below the energy of the K-absorption edge of iron (~ 7.11 keV) from a radioisotope source Fe-55 (5.9 keV). A proportional gas-discharge counter SI-HP registers radiation secondary from the fuel sample, which includes scattered gamma radiation (5.9 keV) and calcium fluorescent radiation (~ 3.7 keV). Sequentially, at the found values of the attenuation filter thickness d1 = 26 mg / cm ² , d2 = 60 mg / cm ^2, the intensity of the secondary radiation is measured. For the fuel of the Karaganda basin, the minimum ash content is chosen equal to 8.3%. The maximum possible ash content is 39.6%. The calcium content in the ash varied in the range of 2.5-15.6%. According to the described technique for finding the optimal values of the attenuation filter thickness, the following are found: thickness d1 = 26 mg / cm ² , d2 = 60 mg / cm ² .

For the selected attenuation filter thicknesses (d1 = 26 mg / cm ² ; d2 = 60 mg / cm ² ), the secondary radiation intensities are measured, and the ash content of the fuel is determined from the family of dependences of the secondary radiation intensity on the ash content of the fuel at different values of the ratio of the measured intensities for the found d1 and d2 (curves cipher). This makes it possible to achieve invariance of the results from fluctuations in the calcium content in the range of changes in the ash content of the fuel from the minimum to the maximum possible.

The table shows the comparative data obtained in the process of experimental testing of the proposed method and the prototype method.

Way Ash content variation range,% Limits of fluctuations of calcium in ash,% Number of fuel samples Error,% abs. The proposed 9-16 3-13 sixteen 0.74 16-39 3-13 28 0.94 Prototype 9-16 3-13 sixteen 0.92 16-39 3-13 28 2.4

The proposed method in comparison with the prototype method is favorably distinguished by increased accuracy in conditions of significant variability of the ash content of the fuel, which significantly expands the scope of its application.

Claims (1)

CLAIM A method for controlling the quality of solid fuel, which consists in irradiating it with gamma radiation with an energy below the K-absorption edge of iron and measuring the intensity of secondary radiation, characterized in that, in addition, on standard fuel samples with the lowest possible ash content and different calcium content in the ash, the dependence of the intensity of secondary from the thickness of the attenuating filter d, the thickness d1 is found from it, at which the intensity of the secondary radiation does not depend on the calcium content in the ash, and on standard fuel samples with the maximum possible ash content and different calcium content in the ash, the dependence of the secondary radiation intensity on the thickness of the attenuating filter is established , the thickness d _{2 is} found from it, at which the intensity of the secondary radiation does not depend on the calcium content in the ash, and on solid fuel of unknown quality, the intensity of the secondary radiation is measured sequentially at the found filter thicknesses d1 and d2, and the ash The fuel density is determined by the intensity of secondary radiation together with the ratio of the intensities of secondary radiation measured at d ₁ and d ₂ .