SU1391739A1 - X-ray fluorescent separator - Google Patents

Description

(21) 4086633 / 23-12

(22) 07/11/86

(46) 04/30/88. Bul sixteen

(71) Bcecoro3Hbrti Research and Design Institute Tsvetmetavtomatika

(72) Yu.P.Betin, .ZhaYin and A.P.Komov

(53) 622.723 (088.8)

(56) Betin Yu.P. et al. Assessing the feasibility of using the X-ray method using differential detectors for small-scale sorting of polymetallic ores. Collection of ACS mining and processing processes, M .: VNIKI, Tsvetmetavtomatika, 1982, p. 33-38.

(54) X-RAY FLUORESCENT SEPARATOR

(57) The invention relates to radiometric enrichment sorting devices. The purpose of the invention is reliability of operation.

The separator includes at least two sensors, each of which is mounted above the ore transporting organ and contains an x-ray tube with a filter and a collimator, as well as a scattered radiation detector and at least three differential detectors placed symmetrically around the tube. The differential detectors of each sensor monitor containing only one of the elements by which the ore is sorted. The detector windows are oriented with the long side across the direction of movement of the ore. The window of the scattered radiation detector is located above the axial zone of the transported ore and is blocked by a replaceable device for adjusting the surface sensitivity of the detector. The replaceable device is made in the form of unevenly across the area of a perforated plate of a material that does not transmit x-rays. 2 hp f-ly, 4 ill.

cl

with so

with CO

The invention relates to radiometric devices for the separation, sorting and testing of mineral raw materials and can be used in the mining industry to enrich non-radioactive ores.

The purpose of the invention is the reliability of work.

FIG. 1 The scheme of the proposed X-ray fluorescent separator is shown; in fig. 2 is a schematic of the separator sensor structure, section; in fig. 3 is a diagram of the placement of the sensor and meter windows relative to the transported ore flow, plan; in fig. A is a device for controlling the sensitivity surfaces of a scattered radiation detector,

The X-ray fluorescent separator contains an ore supply bunker 1 (figs, 1 and bunkers 2 and 3 for collecting sorting products, a vibrating feeder 4, for example, type 280 PT, a transporting unit (vibrator) 5 of the same type, an ore feed rate control device 6 sequentially installed above the conveyor Body 5, the same type of sensors 7 and 8 are connected} 1th with the power supply 9 of the X-ray generation tubes, and register (block 10, which is connected with the actuator 11 controlling the operation of the slide device 12. Position I3 denotes pieces of sorted ore. The separator sensor (FIG. 2) is placed in the casing 14, the window of which is blocked by the charging film 15. The source of primary exciting radiation in the sensor 7, controlling the content of zinc ore, is an X-ray tube 16 of type 3, 5BXB7-Pd with a palladium anode and a selenium or germanium filter 17 with a surface density of 40 mg / cm, which effectively absorbs the low-energy portion of the bremsstrahlung radiation of the tube. The angle of divergence of the beam of primary radiation quanta is limited by the size of the output window of the tube and the collimator 18 of cadmium sheet. The tube 16 is powered from an IRIS-0 type power source 9. The following tube operation mode is set: anodney voltage UQ is equal to 20.0 kV; anode current "I) mA; 1) Channel Injection, 8 V. The source of primary excitation of radiation in sensor 8 is an X-ray tube 16 of type 3, 5BXB7-Pd with filter 17 from yttrium or strontium with a surface density of about 40 mg / cm. The mode of operation of this tube: and 22, 5 kV; mA; , 8 V. Differential Sensor Detectors

8 are set up to isolate the characteristic radiation of lead of the L series and contain filters from selenium about 60 mg / cm thick and radiation radiators from zinc foil about 9 mg / cm thick.

Scattered radiation detector

c includes a proportional counter 19 of the CPM-19 type, a micro-radiator 20 made of lead with a thickness of 20 mg / cm, a screen 21 made of cadmium and an adaptation 22 for adjusting the surface sensitivity of the detector. FIG. 2 also depicts one of three differential detectors of the same type, containing a proportional counter 23 of the CPM-19 type, a filter 24 made of copper foil about 40 mg / cm thick, a target — a radiator 25 of nickel about

9mg / cm, screen 26 of cadmium. Each of the sensors 7 and 8 (D) ig. 3) is installed above the transport body 5 so that the window 27 of the X-ray tube 16 is located above the axial zone of the transported ore, the window 28 of the scattered radiation detector is also located above the axial zone and is oriented long sidewise across the direction of movement of the ore. Windows 29-31 of the differential detectors are rotated with the long side across the direction of movement of the ore so that the partially closed working areas of these detectors form an area intersecting the flow of the ore being transported throughout its width. The window of the detector 28 of the scattered radiation is blocked by the device 22 for

5 for adjusting the surface sensitivity of the detector (Fig. 4), which is a steel plate with a thickness of about 1 mm, on which a perforated pattern is applied unevenly in area. With this, the proportion of the area occupied by the holes is at least one tenth of the plate area and increases from the center of the plate to its periphery.

The separator works as follows.

five

at once.

Pieces of sorted, for example, lead-zinc ore 13 from bunker 1

Feeder # 1 is fed to two successively mounted vibration reference feeders 4 and 5. The vibrating feeder 4, having a feed speed of up to 0.2-0.3 m / s, levels the ore, and the vibrating feeder 5, having a vibrotransmission speed of 0.5-0, 6 m / s forms a stream of ore in the monolayer and supplies it to the working areas of irradiation and measurement of sensor 7, which controls the content of zinc ore, and sensor 8, which controls the content of lead. Under the influence of the radiation of the tube 16 of the sensor 7, secondary radiation is excited in the ore being analyzed, which is detected by the scattered radiation detector and three identical differential zinc detectors. The secondary ore radiation, detected by the scattered radiation detector, passes through the device 22, hits the target radiator 20. The radiation of the target radiator is recorded by a proportional counter 19 The detector detects secondary radiation in a wide spectral range (approximately from 5 to 25 kV) Secondary radiation of ore, registered by each of the differential zinc detectors, passes through the filter 24, hits the target radiator 25, and the radiation of the target radiator (mainly the „LINE of characteristic radiation zinc) counter registers 23.

The signals from sensors 7 and 8 are fed to the input of its unit 10. In the separator, the ratio of the intensities of pulses in the analytic channels to the intensity of the pulses in the channel of scattered printing is used as an analytical parameter, which reduces the error in the analysis of changes geometrical conditions of measurements, component composition of the monitored product, as well as automatically take into account fluctuations of operating modes of X-ray tubes. The recording unit 10 is connected to an actuator I1, which is mechanically connected with a sliding device 12 that controls the flow of ore passing through the working zones of the sensors 7 and 8-. Collection

product sorting occurs in bins 2 and 3.

Claims (3)

1. X-ray fluorescent separator, containing bunkers for ore and sorting products, feeder, transporting organ, ionizing radiation sources placed above it and differential detectors according to the number of controlled chemical elements, one of the differential detectors is installed in a casing with a window covered with a protective film together with a scattered radiation detector and an X-ray tube with a filter and a collimator, and a recording unit connected to the respective detectors by the inputs, and the outputs to the node's actuator sorting, characterized in that, in order to increase reliability of operation, it is equipped with additional housings and an X-ray tube with filter and collima in each of them Hur and the detector of scattered radiation, and the remaining differential detectors mounted in cootvetctvyyushJix additional housings, wherein additional covers placed over the conveying organ. 2. A separator according to claim 1, characterized in that it is provided with 40 45 additional differential detectors, each pair of which is connected in parallel to the corresponding differential detector and mounted in the corresponding casing on both sides of the differential detector in the direction transverse to the direction of movement of the ore, 3. A separator according to claim 1, characterized in that the scattered radiation detector is equipped with an interchangeable device for leveling the surface sensitivity in the detection area, made in the form of a perforated plate overlapping the window of a material that does not transmit x-rays, and the frequency of perforation increases from the center of the plate to periphery. 50 I / X / X / X / X / XyX / iC L A7 / 7 7 g / g / 7 / 2S Phi2.2 g / 2  o °: ° ° Gog ° t ° o °: ° ° o ° ° ooGS / ° - ° ° ° ° ° -; sc t - about oh oh  0 °° 0-0- ° o ° oo ° e ° o ° o ° o ° o: vf o o /: .oo. §0 о 0 ° о ° о J о о о о о о о QO оооо ° о ° о oro °° oooOooo ° oooogoQ rOrOr OrOr oh oh J7 27 FIG. J 22 ° s ° -; sc - g oh oh .oo. o o o QO oooo ogoQ roOr o o oh oh Fy