RU2060062C1 - Process of radiation separation of rare-earth apatite ores - Google Patents

Abstract

FIELD: mining industry. SUBSTANCE: process refers to radiation separation of mineral materials. Process includes feed of portions of ore into measurement zone, measurement of analytical parameters characterizing level of content of basic and accessory elements is ore, determination of value of criteria of separation by measurement of analytical parameters of thorium, carium and ferrum. Product of analytical parameters of mentioned elements is used as separation criteria. Analytical parameters of thorium are found by registration of gamma radiation of ore within range 2.5-2.7 MeV. Analytical parameters of cerium are determined by registration of relation of characteristics X-ray radiation of cerium within range 33.5-36.0 keV to scattered radiation of source of americium-241 within range 45.0-55.0 keO. Analytical parameters of ferrum are determined by registration of relation of characteristic X-ray radiation within range 6.0-6.8 keV to scattered radiation of source of plutonium-238 within range 12.0-15.0 keV. EFFECT: enhanced efficiency of process. 1 dwg

Description

 The invention relates to radiometric concentration of minerals and can be used in the mining industry for sorting and separation of rare-earth apatite ores.

 A known method of radiometric separation, based on measuring the weak natural radioactivity of rare-earth ores and used in the presence of significant correlation between the contents of non-radioactive useful components and indicator radionuclides.

 The method does not meet the production requirements for sensitivity and enrichment efficiency.

 To increase the efficiency of enrichment processes by increasing the separation selectivity, the known method of radiometric separation of loparite ores is used.

 The method includes feeding the ore into the measurement zone, measuring the levels of thorium by the autoradiometric method and rare earth elements of the lanthanum-cerium group by the X-ray radiometric method, using as a criterion for dividing the product of the levels of the content of these elements and the subsequent separation of ore into an enriched product and tailings. This method is adopted as a prototype of the proposed method.

 The disadvantages of the known method [2] are the limited scope of the method only with loparite ores and the difficulty of radiometric separation of rare-earth-apatite ores associated with insufficient sensitivity and information content of the measurements. Insufficient sensitivity and information content are due to the fact that the correlation of the main and related useful ore components with indicator radionuclides (uranium, thorium, potassium) and non-radioactive indicator elements are often different not only for deposits of a particular type of mineral raw material, but may also differ for different technological varieties of ore from one deposit.

 The aim of the proposed method is to eliminate this drawback and increase the sensitivity and efficiency of radiometric separation by increasing the selectivity of separation.

 The essence of the method lies in the fact that the analytical parameters of thorium, cerium and iron are measured in portions of rare-earth-apatite ore and the product of the analytical parameters of these elements is used as a separation criterion. In this case, the analytical parameter of thorium is determined by recording the intensity levels of natural gamma radiation of the ore in the energy range of 2.5-2.7 MeV. The analytical parameter of cerium is determined by irradiating the ore with gamma radiation from radionuclide sources of americium-241 and registering the ratio of the characteristic x-ray radiation of cerium in the energy range of 33.5-36.0 keV to the scattered radiation of americium-241 in the energy range of 45.0-55.0 keV . The analytical parameter of iron is determined by irradiating the ore with x-ray radiation from plutonium-238 radionuclide sources and registering the ratio of the characteristic x-ray radiation of iron in the energy range of 6.0 6.8 keV to the scattered radiation of plutonium-238 in the energy range of 12.0-15.0 keV.

A comparative analysis of the proposed solution with the prototype shows that the claimed method differs from the known one in that in addition to rare-earth laparite ores, rare-earth-apatite ores of various compositions are also identified in which significant positive correlation between phosphorus oxide (P ₂ O ₅ ), thorium, cerium and iron. Due to the lack of sufficiently effective methods for the direct determination of the phosphorus content (the main useful component of ores) in the ore mass, radiometric separation of phosphorus by indirect indications of an increased content of thorium, cerium and iron in the ores is proposed. New operations have been introduced, the analytical parameters of thorium, cerium and iron are measured, the ore is irradiated with gamma radiation from the radioisotope sources of amerations-241 and plutonium-238, the measurement of the natural gamma radiation of the thallium-208 thorium series radionuclide with a line of 2.6 is used as an analytical parameter MeV, as the analytical parameter of cerium, the ratio Kα of the characteristic x-ray radiation (CXI) of cerium to the scattered radiation of the ameration-241 source is used, as the analytical parameter of iron, rel shenie Kα HRIH iron to scattered radiation source of plutonium-238, as separation product using the characteristic parameters of the above analytical elements. Thus, the claimed method meets the criteria of the invention of "Novelty."

 Comparison of the claimed technical solution not only with the prototype [2] but also with other technical solutions in this and related fields did not allow to identify a method or device for radiometric testing, sorting or separation of rare-earth-apatite ores, in which the content of apatite would be controlled by joint measurements of analytical parameters thorium, cerium and iron, or thorium and cerium, and the product of the analytical parameters of these elements would be used as a separation criterion. This allows us to conclude that the technical solution meets the criterion of "Significant differences".

 The drawing shows a diagram of a radiometric separator according to the proposed method.

 The method of radiometric separation of rare-earth-apatite ores is implemented as follows.

 Pieces or portions of enriched ore 1 are fed by a pick-up feeder 2 onto a conveyor belt 3, which are moved past a gamma-ray spectrometric scintillation detector 4 installed in the lead protection unit, a cerium X-ray sensor 5, and an iron x-ray sensor 6. The weak natural radioactive radiation of the ore pieces 1 in the energy range of 2.5-2.7 MeV is sequentially measured by the detector 4, the pulse signals from the detector are processed by the amplifier-driver 7 and the device 8 amplitude selection and accumulate in the drive 9, which includes a recorder and a data storage buffer. From the storage buffer of the drive 9, the readings of the detector 4 through the main line 10 of the computer are fed to the input of the micro-computer 11. The radionuclide sources of americium-241, which are part of the sensor 5 of cerium, excite CRI of cerium in pieces of ore. The pulse signals of the Kα-series of cerium and in the energy range of 45.0-55.0 keV recorded by the proportional counter of the sensor 5 in the energy range of the sensor 5 are processed by pulsed signals of the americium-241 sources scattered by a piece of radiation, are processed by the driver amplifier 12 and the device 13 amplitude selection and accumulate in the drive 14. From the storage buffer of the drive 14 through the highway 10, the readings of the sensor 5 are fed to the input of the microcomputer 11. The radionuclide sources of plutonium-238, which are part of the iron sensor 6, excite HRI iron in pieces of ore. The pulse signals of the Kα-series of iron and in the energy range of 12.0-15.0 keV, the pulse signals of plutonium-238 sources scattered by a piece of radiation from the sources of plutonium-238, recorded by the proportional counter of sensor 6, are processed by the amplifier-former 15 and the device 16 amplitude selection and accumulate in the drive 17. From the storage buffer of the drive 17 through the highway 10, the readings of the sensor 6 are fed to the input of the micro-computer 11. The micro-computer 11 controls the operation of the separator, calculates the analytical parameters of the torus oia, cerium, iron and the value of the separation criterion. According to the commands issued by the microcomputer 11, the actuator drive device 18 includes a group of electro-pneumatic valves 19. If the value of the separation criterion is lower than the threshold, then, as shown in the drawing, at the moment of passage of the piece, electropneumatic valves 19 are triggered, and a piece of ore enters the hopper 20 of tailings . Pieces in which the value of the separation criterion is above the threshold, in free fall fall into the hopper 21 of the enriched product. The implementation of the proposed method is preferred when using a relay type separator.

 PRI me R. Verification of the effectiveness of the proposed method was carried out in relation to the rare-earth-apatite ores of the Seligdarsky apatite deposit, on which detailed geological exploration was performed, and the reserves were approved by the State Reserves Committee of the USSR.

Useful components of the deposit include P ₂ O ₅ , Fe ₂ O ₃ , F, the sum of rare earth elements, and harmful SO ₃ , MgO. The balance reserves of the Seligdar deposit are estimated at 1277.2 million tons of rare-earth-apatite ore (85587 thousand tons of P ₂ O ₅ ) with an average grade of 6.7 P ₂ O ₅ and an ore bearing ratio of 0.75. The capacity of the Seligdar mine and apatite plant is projected at 30 million tons of ore per year, the radiometric sorting or separation of rare-earth-apatite ores does not include feasibility studies for the development of the deposit.

 Apatites of the Seligdar deposit are characterized by a cerium spectrum of lanthanides. The average composition of rare earths in the apatite deposits, La 20.0; Ce 51.0; Pr 5.6; Nd 15.7; Sm 2.3; Eu 0.6; Tb 0.1; Y 2.29; Py 1.4; Ho 0.1; Er 0.7; Tu 0.08; Yb 0.4; Gd 2.0.

Significant positive correlations between the contents of P ₂ O ₅ and thorium, P ₂ O ₅ and cerium, P ₂ O ₅ and iron have been established for the rare earth-apatite ores of martite-quartz-carbonate and hematite-quartz-carbonate compositions. For mixed ores of dolomite, quartz-dolomite, martite-quartz-carbonate and hematite-quartz-carbonate compositions, significant positive correlation relationships between the contents of P ₂ O ₅ and thorium, P ₂ O ₅ and cerium and less pronounced relationships between the contents of P ₂ O ₅ and iron (correlation coefficients are reduced to 0.59-0.69).

There are close correlations between the contents of P ₂ O ₅ and the contents of thorium, cerium, and iron in the rare-earth-apatite ores of the Seligdar deposit. The calculated correlation coefficients are equal: between the contents of P ₂ O ₅ and thorium 0.79-0.98; between the contents of P ₂ O ₅ and cerium 0.82-0.96; between the contents of P ₂ O ₅ and iron for a martite-quartz-carbonate composition of 0.79-0.98; for dolomite, quartz-dolomite and hematite-quartz-carbonate composition of 0.62-0.69.

N

где N_Thi интенсивности гамма-излучения, зарегистрированные каждым детектором в канале тория в энергетическом диапазоне 2,5-2,7 МэВ;
N_Cei интенсивности ХРИ церия, зарегистрированные каждым детектором в энергетическом диапазоне 33,5-36,0 кэВ;
N_S1i интенсивности рассеянного излучения источников америций-241, зарегистрированные в энергетическом диапазоне 45,0-55,0 кэВ;
N_Fei интенсивности ХРИ железа, зарегистрированные в энергетическом диапазоне 6,0-6,8 кэВ;
N_S2i интенсивности рассеянного излучения источников плутоний-238, зарегистрированные в энергетическом диапазоне 12,0-15,0 кэВ.When implementing the method of radiometric separation of rare-earth-apatite ores using a relay type separator, the separation criterion ξ will be described by the expression
ξ

N

where N _{Thi is the} intensity of gamma radiation recorded by each detector in the thorium channel in the energy range of 2.5-2.7 MeV;
N _Cei intensities of CRI of cerium recorded by each detector in the energy range of 33.5-36.0 keV;
N _{S1i the} intensity of the scattered radiation of americium-241 sources, recorded in the energy range of 45.0-55.0 keV;
N _{Fei of} CRI intensity of iron, recorded in the energy range of 6.0-6.8 keV;
N _S2i is the scattered radiation intensity of plutonium-238 sources recorded in the energy range of 12.0-15.0 keV.

 Comparison of the expected results of the process of lump separation of rare-earth-apatite ores according to the proposed technical solution and traditional methods of lump separation based on the use of only natural radioactivity or only the X-ray radiometric method with the separator RRS-50.

The positive effect of the claimed technical solution for the Seligdar field is characterized by the following series of quantitative improvements of the piecewise separation process relative to the traditionally known separation method:
the value of the measured analytical parameter of the proposed technical solution is higher by 3.7-58.5 times;
the working sensitivity of multi-parameter lumpy separation increases by 4.7-19.3 times;
the resolution threshold of the proposed technical solution pokuskovy separation in 4.1-16.9 times higher;
it becomes possible to separate poor and off-balance rare-earth-apatite ores with a low content of P ₂ O ₅ (1.0-3.5% P ₂ O ₅ ); these ores are not available for separation on known separators;
due to an increase in the working sensitivity, the productivity and selectivity of the bite separation increase 2.2-3.8 times.

, (2) где Δ ξ=ξ₂-ξ₁- разность величины аналитических параметров вблизи фоновых значений;
ΔC=C₂-C₁ разность величин содержаний вблизи фоновых значений содержаний.The working sensitivity of the proposed technical solution in the separator is determined by the expression
Q _p =

, (2) where Δ ξ = ξ ₂ -ξ ₁ is the difference in the magnitude of the analytical parameters near the background values;
ΔC = C ₂ -C _{1 the} difference in the values of the contents near the background values of the contents.

, (3) где K коэффициент надежности;
σ_ф среднеквадратичная погрешность фонового значения аналитического параметра;
Q_р- рабочая чувствительность сепаратора отношение изменения аналитического параметра к соответствующему изменению содержания.The resolution threshold of the proposed technical solution for piecewise separation when determining the content of the analyzed element C _{p is} determined by the expression
C _p =

, (3) where K is the reliability coefficient;
σ _f mean square error of the background value of the analytical parameter;
Q _p - the working sensitivity of the separator is the ratio of the change in the analytical parameter to the corresponding change in content.

 When calculating the economic effect, the following initial data were adopted: the volume of processing of rock mass is 30 million tons per year; the output of tailing tailing tailings for option B-1 is assumed to be 15% for option B-2 equal to 20%, the reduction in rock mass due to primary processing will be 4.5 million tons per year for option B-1, for option B-2 6 million tons of ore per year. According to the feasibility study for the development of the deposit, radiometric separation at the Seligdarskoye deposit is not provided, therefore, the calculations of the annual economic effect from the introduction of the proposed technical solution have been performed with respect to the basic version of the development of the deposit according to the feasibility study.

Claims (1)

 A method for radiometric separation of rare-earth apatite ores, including feeding portions of ore to a control position, measuring analytical parameters characterizing the levels of the main and related elements in the ore, determining a separation criterion according to the product of the analytical parameters of the elements, and subsequent separation, characterized in that the analytical parameters of thorium are calculated , cerium and iron, the analytical parameter of thorium is determined by the value of the level of intensity of gamma radiation of ore portions in energy a chemical range of 2.5 2.7 MeV, the analytical parameter of cerium is calculated as the ratio of the intensity of the characteristic x-ray radiation of cerium in the energy range of 33.5 36.0 keV when irradiating portions of ore with gamma radiation from radionuclide sources of americium-241 to the scattered radiation intensity of americium-241 in the energy range of 45–55 keV, and the analytical parameter of iron is calculated as the ratio of the intensity of the characteristic x-ray radiation of iron in the energy range of 6.0 to 6.8 keV when irradiating portions of ores X-ray sources radionuclide plutonium-238 to the intensity of the scattered radiation of plutonium-238 in the energy range of 15 December keV.

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