SU1673936A1 - Method and apparatus for x-ray radiometric or gamma-gamma ore testing - Google Patents

Abstract

The invention relates to the field of nuclear-physical testing methods and can be used to test mine workings, ores on a conveyor belt and in transport tanks. The aim of the invention is to improve the accuracy of testing by compensating for the effect of changes in the distance between the detector and the surface of the ore to be tested. The method of X-ray radiometric or gamma-gamma ore testing consists of simultaneously irradiating ore with radiation from several sources, recording the intensities of characteristic X-ray emissions of detectable elements or scattered radiation by ores and determining the contents of elements according to the registered intensities. several sources from which the closest to the detector irradiates the ore in a wide solid angle, and the rest The screens are shielded from the detector by flat moving screens. Pre device is configured as follows. First, only the first source is placed in it, the dependence of the intensity of the detected radiation on the distance H from the probe to the model surface is removed on the ore model and, given an error of ± δ measurement caused by a change in the distance H within the required limits from H _min to H _max , select the inversion zone (from H _min to H ₁ ) of the H distance, within which the change in the intensity of the detected radiation does not exceed the specified error ± δ. Then, a second source is placed in the probe and, by adjusting the angle ϕ _{1 of the} screen tilt and distance from it to the detector, achieve that the change in the total intensity of the detected radiation does not exceed the specified ± δ error in the more extended (to H ₂ ) inversion zone. Then the next source is placed in the zone and the operations are repeated until the inversion zone is expanded to the desired (H _max ) value. 2 sec. and 1 z. p. f-ly, 3 ill.

Description

The invention relates to nuclear geophysical testing methods and can be used to test mining workings, ores on a conveyor belt and in transport tanks.

The aim of the invention is to improve the accuracy of testing by compensating for the effect of changes in the distance between the detector and the surface of the ore to be tested.

Figure 1 shows schematically an apparatus for carrying out the method; Fig. 2 shows the dependences of the intensities of secondary radiation on the distance between the probe and the surface of the ore using a different number of sources; in FIG. 3, the intensity dependences of the characteristic X-rays of molybdenum and the radiation scattered by the empty rock as a function of the distance between the probe and the surface of the ore.

A device for carrying out the proposed method includes a radiation detector 1 with a collimator 2, several sources of 3-8 gamma or x-ray radiation, located at different distances from the detector. The first sources 3 and 4 closest to the detector are not shielded and irradiate the ore being tested in a wide solid angle. More distant sources (second pair of sources 5, 6, third - 7. 8, etc.) are shielded from the detector by flat or curved convexity directed to the detector by screens 9 and 10, 11 and 12, respectively, at angles p, (pi and t. to the perpendicular to the ore surface. The surface area of the ore from which secondary radiation enters the detector is determined by the angle B of the detector's collimator: it is determined based on the required contrast of the analytical parameter and the representativeness of single measurements.

The method is carried out as follows.

First, only the first pair of sources 3 and 4 close to the detector that do not have a screen are placed in the probe, and the dependence of the secondary radiation intensity (or analytical parameter value) on the change in the distance H between the probe and the surface of the ore is removed in the ore model (curve 13 in Fig. 2 ). The activity of this source, its distance to the detector (probe length), as well as the position of the detector screen are selected so as to provide the necessary concentration sensitivity of the measurements to the content of the element being detected (analytical line contrast) and the minimum limit Nmin of the compensation zone for the change in the distance H between the probe and the surface of the ore.

The obtained dependence (curve 13 in Fig. 2) separates the inversion zone (interval from Hi to H2) in which the changes in the intensity of the secondary radiation do not go beyond the predetermined measurement error of ± e. Then in the probe place the second pair of sources 5 and 6. Their activity can be any. The angle of inclination of the screen of this source is chosen so that, starting from the distance H2 between the probe and the surface of the ore, the detector detects the secondary radiation from this source. At the same time, the length of the probe is adjusted so that the total intensity of the secondary radiation does not exceed the upper permissible limit, bounded by the intensity obtained using the first source and the specified error ± d. If the total secondary radiation intensity exceeds this limit,

0 probe length is increased; In this case, the mind's tilt angle of the source screen should also be increased, fulfilling the condition that the detector detects secondary radiation from the second pair of sources only from the distance H2.

5 The dependence of the total intensity of the secondary radiation (or the value of the analytical parameter) on the change in the distance H between the probe and the surface of the ore is measured, and the distance Hz is determined at which this intensity falls to a value determined by a given accuracy and intensity, obtained using only the first sources (dependence 14 figure 2). Into the probe

5 inserts a third pair of sources 7 and 8, which are used to similarly achieve the constancy of the total intensity of the secondary radiation with an accuracy of ± d in the range of changes in distance from

0 Нз до Нз (dependence 15, figure 2). These operations are repeated until the entire required range of variation of the distance between the probe and the surface of the ore being tested is provided, i.e. up to the maximum required boundary of the inversion zone is Nmax (dependence 16, figure 2).

After performing the described operations, the probe is considered to be tuned and ores can be tested, during which

0

a change in the distance between the probe and the surface of the ore being tested in the range from N min to N max will not affect the measurement results within the specified error of ± e.

5, as an example of the practical implementation of the proposed method and description of the operation of the device, testing of molybdenum ore in trolleys and dump trucks is considered.

The probe of the ore controlling station contains three radioisotope sources of cadmium-109 with an activity of 0.15; 0.66 and 2.37 GBC (as they are further away from the detector) and a proportional xenon counter SRPO-304 as a detector. The angle $ for the detector screen was 20 °. The first pair of sources was not shielded; for the second and third pairs of sources, the angles of inclination of the screens (respectively, were 35 and 45 °). The length of the probes (the distance between the detector and sources), respectively, was 80, 160 and 250 mm.

Measurements were carried out on models that mimic molybdenum ore and waste rock.

Fig. 3 shows the dependence 17 of the intensity of the characteristic x-ray radiation of molybdenum (17.3 keV) on the distance between the surface of the medium and the probe, and the dependence 18 on the radiation of cadmium -109 scattered by the empty rock.

As seen from FIG. 3, the total intensity of the characteristic x-ray radiation of molybdenum (curve 17) in this case remains constant with a given accuracy of ± 10% relative to the average level when the distance between the probe and the surface of the model medium changes from 20 to 60 cm, t. e. within 40 cm. The inversion zone for scattered gamma radiation in the region of the molybdenum analytical line (curve 18) is even wider.

Thus, the method and the device, as compared with the known ones, have the ability to eliminate the effect of changing the distance between the probe and the surface of the ore being tested over a wide range with a predetermined accuracy, have a simple algorithm for adjusting the probe of the device, and make it possible to use double and higher probes. any sources with available activity.

Claims (3)

1. The method of x-ray radiometric or gamma-gem-testing of ores. consisting of simultaneous irradiation of the ore being tested with x-ray or gamma radiation from two sources, the first of which is removed from the detector by a distance equal to or less than the minimum possible distance Nmin from the detector to the ore surface, recording the intensities of the characteristic x-ray emissions of the elements being detected or scattered ore radiation and determination of the contents of elements according to the values of registered intensities; about t-that, h-oh. In order to improve the accuracy of testing by compensating for the effect of changes in the distance between the detector and the surface of the ore being tested, the ore is additionally irradiated with radiation from additional sources, placed between the first and second sources and moving protective shields shielded from the detector, prior to testing, the dependence of the intensity of the per-source radiation due to the top source, from the distance of the detector's position to the model surface, is irradiated in a wide solid angle, set the value of the error (± e) of measuring the intensity of the detected radiation caused by a change in the distance H from the detector to the surface of the ore within the required limits from NMIn to the maximum possible distance Nmax to the surface of the ore and isolate on inverse dependence the inversion zone from Nmin to H; within which the change in the registered intensity does not exceed the specified pofeshnost ± d, then adjusting the angle of the screen closest to the alternate source and changing the distance from it to the detector, remove the dependence of the total intensity of the detected radiation due to this and the first sources from the distance from the detector to the surface of the model, starting from the distance Hi, the zone from the distance G to the distance HZ. where the change in total intensity is not exceeds the specified error ± d. perform the described operations with the following additional and first and second sources until the zone width, where the change in the total intensity of the detected radiation due to all sources does not exceed the specified error, reaches the maximum possible distance Hmax from the detector to the model surface, after what all samples are tested. 2. Device for X-ray radiometric or gamma-gamma-testing of ores. containing measuring console, detector and radiation sources with movable screens, characterized in that. what. in order to increase accuracy, the detector is additionally equipped with a flat screen located on the side of the sources and made with the possibility of angular movement relative to an axis perpendicular to the plane passing through the axes of the sources, and the protective moving screens of all sources, except the one closest to the detector, are made flat and directed at an angle less than 90 ° to the direction of the protective screen of the detector. 3. The device according to claim 2, characterized by the fact. that the detector and source screens are curved and convex to each other. eleven -and ± I ( --I lA.ycji.ed. , 1.0 -6 USо Hi n P + H2 YES 1 / b L // 7 Vue. g # 600 7 500 worn tooJ, UHff. / C ten% 01 go zow Fmz 50 60 msm