SU473451A1 - Method of radioactive logging - Google Patents

Description

The invention relates to methods of field and geophysical exploration of coal exploration wells, for example, using scattered gamma radiation in order to determine the power, structure and ash content of a coal seam.

The known method of radioactive logging, designed to determine the ash content of coal, which consists in recording the gamma radiation of radiation capture of thermal neutrons in the energy range above 5 MeV, measure the ratio of this spectral intensity to the total integrated intensity of gamma radiation of radiation capture the intensity of secondary neutron radiation) and the value of the resulting ratio is judged on the ash content of the coal ilast.

The disadvantage of the known method is that it does not allow determining simultaneously the structure and ash content of coal seams due to the great depth of neutron penetration into the rock, therefore the method is only suitable for studying powerful coal seams of simple structure. In addition, due to the small size (about two) of the amplitude of the anomaly (due to a change in the intensity ratio), a significant increase is required in the transition from host rocks to ashless coal.

recorded intensities to increase the accuracy of the ash content by reducing the statistical error.

The purpose of the invention is to improve the accuracy of simultaneous determination of the structure and ash content of coal seams.

For this, according to the proposed method, the scattered gamma radiation of an artificial source of gamma rays is used. In the spectrum of the scattered gamma radiation, a spectral region is selected in which a maximum increase in spectral intensity is observed upon transition from rocks of average atomic number to coal, and the structure and ash content of coal beds is determined from the magnitude of the spectral intensity recorded in this region.

Claims (3)

Using spectrometry equipment to implement the proposed method, the spectral intensity of scattered gamma radiation in the range of 40-60 keV is recorded. When using integrated equipment, a gamma-radiation source with energy less than 60 keV and a gamma-ray detector with maximum spectral efficiency are used. less than 60 keV. The essence of the proposed method is explained in FIG. 1, which shows the model spectra of the scattered gamma radiation, as well as the ash content (° / o) of the coal under study. The spectrum was not obtained for the source of thallium-204 with a probe length of 10 cm. The width of the measuring channel during the removal of the spectrum was 10 keV. The graphs show that the amplitude of the anomaly (dotted curve) for the spectral intensity during the transition from the .Hx rock formation (A 100%) to ashless coal (A 12) is slightly different from unity at E 100 keV, but increases dramatically in the low energy region where there is a pronounced maximum at energies of about 50 keV. In this case, the absolute magnitude of the anomaly amplitude is equal to 10. Such a large increase in the recorded spectral intensity makes it possible to increase the accuracy of reading the ash content of the coal. In addition, the large magnitude of the anomaly amplitude significantly reduces the influence of such an interfering factor as irregular changes in the density of the coal. In this case, the fraction of the density effect is less than the total magnitude of the anomaly amplitude; therefore, real changes in the density of the constant ash angle cannot lead to ash count errors of more than 1%. These anomalous effects are already achieved at a measuring probe length of 10 cm, therefore, in practical implementation of the method, simultaneously with the calculation of ash, it is possible to determine the power and structure of the coal seam with an accuracy of ± 2 cm. The maximum amplitude of the anomaly for a spectral intensity of 40 - 60 keV rock to coal is observed for any primary gamma quantum energy. However, under conditions of equal length of the probe for sources emitting high-energy gamma rays, the absolute magnitude of the anomaly amplitude at the maximum decreases. This is clearly seen from the graphs in FIG. 2, where selenium-75 is used as a source of primary gamma quanta (the main gamma lines are 138 keV, 268 keV, 405 keV). A more than twofold increase in the average energy of the primary radiation resulted in a 40% decrease in the amplitude of the anomaly at the maximum. An increase in the ash content of the coal also leads to a decrease in the maximum value of the anomaly amplitude, while the position of the maximum remains almost unchanged. Based on these regularities, two options can be proposed for the practical implementation of the proposed method. When using downhole spectrometric equipment, the required length of the measuring probe is selected and, regardless of the source type, the spectral intensity is recorded in the range 40-60 keV. The results of the practical implementation of this measurement variant are shown in FIG. 3. A source of selenium-75, a probe 10 cm long and a downhole spectrometer was used in the works. Comparison of core sampling data (column a) and the amount of ash calculated by the proposed method (column e) shows the high accuracy and objectivity of the new method. When using integrated-type downhole equipment, it is necessary to maximally weaken the effect of the density effect, for which radiation sources with energy lying in the region of the maximum amplitude of the anomaly are used, or slightly lower, and detectors with the maximum spectral efficiency in the same energy range. The results of the practical implementation of this measurement variant are shown in FIG. 4. The work was carried out with a probe length of 10 cm, a thulium source of 170 (main lines 51 keV and 82 keV) and a detector in a gas discharge meter of the MS type (the maximum spectral efficiency is at a gamma quantum energy of 25 keV). Similar results can be obtained with a Na J (Te) scintillation detector 0.5–2 mm thick (the maximum spectral efficiency lies in the region of 20–40 keV). From the graphs in FIG. 4 that under the specified registration conditions the proposed measurement method has the necessary accuracy and detail. Claim 1. A method of radioactive logging, which consists in registering the scattered gamma radiation of an artificial source, characterized in that, in order to increase the accuracy of determining the structure and ash content of coal seams, the spectral region in the spectrum of scattered gamma radiation is observed, in which the maximum the increase in spectral intensity during the transition from the rocks of the average atomic number to coal, and the magnitude of the spectral intensity recorded in this region determines the structure and ash be coalbed. 2. A method according to claim 1, characterized in that, in order to use spectrometric apparatus for the implementation of the method, the spectral intensity of the scattered gamma radiation in the range of 40-60 keV is recorded. 3. The method according to claim 2, characterized in that, in order to use integrated equipment for implementing the method, a gamma-ray source with an energy of less than 60 keV and a gamma-ray detector with maximum spectral efficiency in the same gamma-ray energy range are used. v unnlnuH 20 P 180 cab 75 Se 180 cab BUT 60Ac, ° lo100 60 Olycfi.ed.