RU2165793C2 - Integrated method for recovering gold in the processing of copper pyrite ores and rejected products - Google Patents

Abstract

FIELD: mining industry and precious metal technologies. SUBSTANCE: invention relates to technology of concentration and processing of copper pyrite ores and also to processing of old wastes of out-of-budget copper pyrite and pyrite-polymetallic ores and reject products from ore-dressing and metallurgy in North and Central regions of Ural and Siberia. Ore is transported, subjected to express analysis involving x-ray-radiometric technique, after which follow x-ray-radiometric great-portion sorting and single-lump separation, centrifugal concentration on Knelson concentrators, and in-vat bacterial and chemical leaching involving heating of solution in winter and autumn-spring periods. Sorting and separation give 5 products with different contents of gold: enriched product, three intermediate products, and nonutilizable waste. Enriched product is processed to recovery gold. The first intermediate product is subjected to one or two centrifugal concentrations and the second one is concentrated one or two times. Tailings of the two processed intermediate products are combined with third intermediate product and subjected to leaching. EFFECT: enabled involvement of poor and out-of-budget ores into processing. 8 cl, 1 dwg, 1 tbl

Description

 The invention relates to a technology for the beneficiation and processing of copper-pyrite, pyrite-chalcopyrite, pyrite-chalcopyrite-sphalerite ores for the extraction of gold, as well as the processing of old (stale) dumps of off-balance copper-pyrites and pyrite-polymetallic ores and dump products of concentration and metallurgy in the northern and central regions of the Urals and Siberia.

 A combined method of processing copper ores is known, including transportation of ores, their rapid analysis by radiometric methods, heap bacterial-chemical leaching (see RF patent 2051748 C1, B 03 B 7/00, 01/10/1996).

 The disadvantage of this method is the inability to leach in the winter and autumn-spring periods.

 A known method of processing gold-bearing ores, including crushing, grinding, screening of ore and further vat bacterial and chemical leaching of gold (Polkin S.I. and other Technology of bacterial leaching of non-ferrous and rare metals. M: Nedra, 1982, S. 162, 200 )

 The disadvantage of this method is the high capital and operating costs.

 The closest analogue to the proposed method is a combined method for the extraction of gold in the processing of copper-pyritic ores and waste products, including transportation of ores, their rapid analysis, X-ray radiometric method, regulation of the boundary content of the product by X-ray radiometric sorting and separation, using parameters characterizing features of the geochemistry of gold, clarke concentrations of copper, tellurium, silver, zinc and other elements (Fishman M.A. et al. scheniya non-ferrous and rare metals, 1967, p. 16-19).

 The disadvantage of this method is the impossibility of involving in the development of significant volumes of poor balance and off-balance ores, dump products, as well as stale concentrates, in addition, the low efficiency of gold extraction from ores.

 To date, over 200 tons of gold has accumulated in the wastes of mining and processing plants of copper-pyrite and pyrite-polymetallic ores and stagnant concentrates. The cost of gold in pyrite ores and stagnant concentrates is commensurate with the cost of copper and zinc. Extraction of gold and silver in passing, the degree of extraction of gold and silver in the existing processing does not exceed 20-50%.

 The aim of the claimed invention is to increase the extraction of gold, improve the environment in the regions of the Urals and Siberia by involving in the processing of poor balance and off-balance ores of dump products and stale concentrates.

 To achieve this goal in the proposed combined method for the extraction of gold in the processing of copper-pyrite ores and waste products from ores located in the North, including the transportation of ores, their rapid analysis by X-ray radiometric method, regulation of the boundary content of the product by X-ray radiometric sorting and separation, using as parameters characterizing the features of the geochemistry of gold, clarke concentrations of copper, tellurium, silver, zinc and other elements, realizing x-ray radiometric large-scale sorting and piecewise separation, separation of the ore into five products - enriched products with a gold content of more than 2.5-4.0 g / t, which are sent for processing to extract gold, intermediate product PP-1 with a gold content of 1, 8-2.5 g / t or 2.2-4.0 g / t, which is in native form or in the form of tellurides, an intermediate product of PP-2, with a gold content of 1.1-1.8 g / t, or 1.3-2.2 g / t, which is in intergrowths with sulfides, the intermediate product PP-3 with a gold content of 0.15-1.1 g / t silt 0.15-1.3 g / t and tailings with a gold content of less than 0.15 g / t, which are sent to the dump, for each of the products PP-1 and PP-2, one or two processing operations are carried out at a Knelson concentrator, the resulting heavy fraction is sent to gold processing, and the tailings are sent to the intermediate product PP-3 for a bacterial chemical leaching, which is carried out with heating of the bacterial solution in the winter, autumn and spring, and intensifies the activity of the bacterial bacterial chemical leaching bacteria and adjust the volumes of PP-1, PP-2, PP-3, enriched products and tailings using a microcomputer, determine the gold content in the portions of the tailings, while the portions of the tailings are returned to the inlet of the lump separation separator if the gold content in portions of tailings above the optimal gold content in the tailings of processing plants, determine the gold content in the tailings of the separation after the return of the portions, the information obtained is used to control and regulate the percentage ess.

 In addition, this goal is achieved by the fact that they unite into geochemical samples for the main types of ores deposits of homogeneous ore with a minimum composition, clarks of its concentrations that reflect the degree of accumulation of gold in ores and the gold accumulation coefficient for gold are used as parameters characterizing the features of gold geochemistry pyrite formation is defined as weighted average by the number of deposits in each type of ore, the zones of maximum accumulation of gold in copper-pyrite deposits are set abalance sections of disseminated pyrite-chalcopyrite-sphalerite ores.

где N_Cui - интенсивности характеристического рентгеновского излучения (ХРИ) меди, зарегистрированные каждым детектором эстафетного сепаратора в энергетическом диапазоне 7,8- 8,2 кэВ;
N_S1i - интенсивности рассеянного излучения источников Плутония-238, зарегистрированные в энергетическом диапазоне 13,6- 16,8 кэВ;
N_Tei - интенсивности ХРИ теллура, зарегистрированные в энергетическом диапазоне 27,2-27,5 кэВ;
N_S2i - интенсивности рассеянного излучения источников Америций-241 зарегистрированные в энергетическом диапазоне 48-56 кэВ;
N_Agi - интенсивности ХРИ серебра, зарегистрированные в энергетическом диапазоне 22,0 кэВ;
N_S3i - интенсивности рассеянного излучения источников Америций-241, зарегистрированные в энергетическом диапазоне 48,0-59,0 кэВ;
N_Pbi - интенсивности ХРИ свинца, зарегистрированные в энергетическом диапазоне 11,5-13,0 кэВ;
N_S4i - интенсивности рассеянного излучения источников Кадмий-109, зарегистрированные в энергетическом диапазоне 19,0-21,5 кэВ;
N_Zni - интенсивность ХРИ цинка, зарегистрированные в энергетическом диапазоне 8,4-8,8 кэВ;
N_S5i - интенсивности рассеянного излучения источников Кадмий-109, зарегистрированные в энергетическом диапазоне 19,0-21,5 кэВ;
N_Sbi - интенсивности ХРИ сурьмы, зарегистрированные в энергетическом диапазоне 26,1-26,5 кэВ;
N_S6i - интенсивности рассеянного излучения источников Америций- 241, зарегистрированные в энергетическом диапазоне 48,0-59,0 кэВ;
N_Bii - интенсивности ХРИ висмута, зарегистрированные в энергетическом диапазоне 10,5-10,9 кэВ;
N_S7i - интенсивности рассеянного излучения источников Кадмий-109, зарегистрированные в энергетическом диапазоне 19,0-21,5 кэВ;
n - количество рентгенорадиометрических детекторов эстафетного сепаратора.In addition, it is achieved by the fact that X-ray radiometric sorting and separation are realized by using as a criterion for the separation of ores the product of the analytical parameters of the indicator elements of copper, tellurium, silver, lead, zinc, bismuth, while the criterion for the separation of copper-pyrite ores is determined by the expression

where N _Cui are the intensities of the characteristic X-ray radiation (XRD) of the copper recorded by each detector of the relay separator in the energy range of 7.8-8.2 keV;
N _S1i are the intensities of the scattered radiation of Plutonium-238 sources recorded in the energy range of 13.6–16.8 keV;
N _Tei are the HRI intensities of tellurium recorded in the energy range of 27.2-27.5 keV;
N _S2i — scattered radiation intensities of Americium-241 sources recorded in the energy range 48-56 keV;
N _Agi — silver CRI intensities recorded in the energy range of 22.0 keV;
N _S3i — scattered radiation intensities of Americium-241 sources recorded in the energy range 48.0–59.0 keV;
N _Pbi — lead CRI intensities recorded in the energy range of 11.5–13.0 keV;
N _S4i are the intensities of the scattered radiation of Cadmium-109 sources recorded in the energy range of 19.0-21.5 keV;
N _Zni is the CRI intensity of zinc, recorded in the energy range of 8.4-8.8 keV;
N _S5i are the intensities of the scattered radiation of Cadmium-109 sources, recorded in the energy range of 19.0-21.5 keV;
N _Sbi — antimony CRI intensities recorded in the energy range of 26.1–26.5 keV;
N _S6i - scattered radiation intensities of Americium-241 sources recorded in the energy range 48.0-59.0 keV;
N _Bii — bismuth CRI intensities recorded in the energy range of 10.5-10.9 keV;
N _S7i are the intensities of the scattered radiation of Cadmium-109 sources recorded in the energy range of 19.0-21.5 keV;
n is the number of x-ray radiometric detectors of the relay separator.

 At low linear correlations of gold with indicator elements Cu, Te, Ag, Pb, Zn, Sb, Bi, correlation relationships are estimated using the threshold correlation coefficient.

When determining the linear correlation of the threshold correlation coefficient (r _n ), the values of the contents of Au, Cu, Te, Ag, Pb, Zn, Sb, Bi located in a narrow region of the boundary contents of gold and related elements Cu, Te, Ag, Pb, Zn are used. Sb, Bi.

где Au_n - пороговое (граничное) содержание золота в расчетах для ПП-1 и ПП-2 принято 0,8 г/т;
Aui - содержание золота в отдельном образце или пробе;
η_n - пороговое значение аналитического параметра, соответствующего граничному содержанию Cu, Te, Ag, Pb, Zn, Sb, Bi, относительно которых производится разделение кусков или порций;
η₁ - значение аналитического параметра соответствующего образца или пробы;
γ_i - весовая доля куска или пробы из n образцов или проб.Calculations are performed by the expression

where Au _n is the threshold (boundary) gold content in the calculations for PP-1 and PP-2 accepted 0.8 g / t;
Aui - gold content in a single sample or sample;
η _n is the threshold value of the analytical parameter corresponding to the boundary content of Cu, Te, Ag, Pb, Zn, Sb, Bi, relative to which pieces or portions are separated;
η ₁ is the value of the analytical parameter of the corresponding sample or sample;
γ _i is the weight fraction of a piece or sample of n samples or samples.

 At low linear correlation values of Au, Cu, Te, Ag, Pb, Zn, Sb, Bi, their threshold correlation coefficient is significantly higher and allows one to obtain positive technological indicators for the isolation of intermediate products PP-1, PP-2 and PP-3.

 This goal is also achieved by the fact that they realize one or two processing operations of PP-1 at a Knelson concentrator, while the product PP-1 with a size of -5 + 0 mm is first sent to screening, the mined mass of +2.0 mm is subjected to grinding, and -2.0 mm is sent to the first operation at a Knelson concentrator, at a particle size of more than +0.1 mm the PP-1 product is subjected to grinding, and at a fineness of -0.1 mm, it is sent to a second operation at a Knelson concentrator, a heavy fraction is obtained at a Knelson concentrator and sent for break gold processing, and the tails are sent to PP-3 for a vat of bacterial-chemical leaching.

 The goal is also achieved by the fact that they carry out one or two processing operations of PP-2 at a Knelson concentrator, while with a fineness of copper-pyrite ores PP-2 less than -0.08 mm they realize the first processing operation of PP-2 at a Knelson concentrator, and at a size of more than +0.08 mm PP-2 is subjected to grinding, the ore mass of PP-2 with a grain size of -0.06 mm is sent to the second processing operation of PP-2 at a Knelson concentrator, and the ore mass of PP-2 with a grain size of +0.06 mm is subjected to grinding, the heavy fraction obtained at the concentrator is sent to the slave gold swelling, and the tails are sent to the PP-3 channel bacterial-chemical leaching.

 Geological and technological mapping of the ore deposit or stale dumps is carried out with the determination of the spatial variability of the optimal size of native gold grains, when the spatial variability of the optimal size of the native gold grains is emitted, the studied ore deposit or old, stagnant dumps are divided into separate small ore blocks and in each of them determine the optimal size of the native Zolotins, they realize the processing of ores of individual small ore blocks at a Knelson concentrator according to the optimal coarse gold grains in each ore block.

 PP-3 is directed to bacterial-chemical vat leaching with heating of the bacterial solution in winter, autumn and spring when using a tank for heating hot water and a pump for circulating hot water in water jackets, eight sections of the leaching vat are heated, one vat for clarifying the solution , two sections of the tank for the deposition of gold and a reservoir for spent solutions, the spent solution is reinforced with cyanide and pumped using a pump to leach.

The solutions are heated in sections of the leach vat, in the vat to clarify the solution and precipitate gold, as well as the waste solution reservoir using double walls - water vats of the vats, with a distance between the walls of 3-7 cm, hot water is continuously pumped through the water jacket, heated in the tank and fed to the shirts using a pump, and in frosts below -20 ^o C in the tank section for leaching, clarification of the solution, and deposition of gold for additional heating of solutions, portable batteries are installed, through which hot water is continuously pumped.

 The proposed method of combined processing will significantly increase the degree of extraction of gold from copper-pyrite ores and pyrite-polymetallic stagnant concentrates and waste products.

 The drawing shows a flow diagram of the combined processing of copper-pyrite ores and waste products in the extraction of gold in the northern regions of the Urals and Siberia.

 The initial copper-pyritic pyrite-chalcopyrite or pyrite-chalcopyrite-sphalerite ore with a grain size of less than 500 mm (-500) 1 is screened 2 in order to isolate the ore mass larger than 300 mm (+300), ore +300 is crushed 3 and sent to large-size x-ray radiometric sorting trolleys 4, where correlation bonds of gold with elements Cu, Te, Ag, Pb, Zn, Sb, Bi are used. Using an ore control station (RCC) 5 of large-scale sorting, the rock mass is divided into six products: rich ore 6, ordinary ore 7, poor ore (PP-1) 8, off-balance copper-pyrite ores (PP-2) 9, off-balance low-grade ores (PP-3) 10, tailings 11. Rich gold-bearing ore with a gold content of more than -2.5-4.0 g / t and higher without piece separation is sent to the ore quality averaging unit 12. Ordinary gold-containing ore is sent to screening 13 and crushing class +150 mm 14 followed by washing 15 and removal with drying and thickening the slag 16. Next, the mass 7 is sent to screening 17 with separation of the fineness classes -200 +80 mm (18), fineness -80 +50 mm (19), fineness -50 +30 mm (20) and piecewise x-ray radiometric separation: fineness class 200 +80 mm (21), particle size class -80 +50 mm (22), particle size class -50 +30 mm (23) with separation of separation products into dump tailings 24 and concentrate 25. Blade tailings of piecewise separation of ore quality averaging block 26 , sent to the separation dump 27, and concentrate 25 sent to the unit for averaging the quality of ores 12. Enriched ore 6 and concentrate 25 p the operation of averaging the quality of the ores 12 is carried out and the product is sent to the hopper of the total enriched product 28, from where it is sent to block 60.

 After X-ray radiometric sorting of trolleys, where correlation bonds of gold with the elements Cu, Te, Ag, Pb, Zn, Sb, Bi are used, the intermediate product PP-1 is sent to centrifugal concentration unit 29-38 (drawing) (Knelson concentrator). The gold-bearing mining mass of the intermediate product PP-2 is sent to a centrifugal concentration unit 39-58. The gold-bearing mining mass of the intermediate product PP-3 is sent to a block 59-69 of a bacterial-chemical vat leaching unit with a heated bacterial solution. To select the size of grinding size, the gold-bearing ore mass PP-1 with a grain size of -5 + 0 mm is screened 29. The resulting over-sieve product with a grain size of + 2 mm is subjected to additional grinding 30, and the under-sieve is sent to the first enrichment operation at Knelson concentrator 31, block 29- 38, where the heavy fraction 32 and product 33 are recovered for re-screening 34, after which the ore mass of fineness less than -0.1 mm is subjected to a second enrichment operation at Knelson concentrator 36, block 29-38, and the ore mass of PP-1 is larger with a thickness of more than +0.1 mm is subjected to additional grinding 35. In the second operation, a heavy fraction 37 and tails 38 are isolated at a Knelson concentrator 36. The heavy fraction is sent to gold processing, and the tails are sent to PP-3 for processing by a bacterial chemical tank with heating bacterial solution, block 39-48.

 The ore mass PP-2 is screened 39, the obtained fraction with a size of less than -0.08 mm is subjected to a first enrichment operation at a Knelson concentrator 41, block 39-48, and the ore mass PP-2 with a grain size of more than + 0.08 mm is subjected to additional grinding 40. At the Knelson concentrator 41, a heavy fraction 42 and tails 43 are isolated.

 The ore mass PP-2 with a particle size of less than -0.06 mm is subjected to a second enrichment operation at a Knelson concentrator 46, block 39-48. The ore mass PP-2 with a particle size of more than + 0.06 mm is subjected to additional grinding 45. The second operation at a Knelson concentrator 46 releases a heavy fraction 47 and tailings 48.

 After choosing the optimal size of the grain size of grinding the ore, the processing of the ore is carried out with the selected grain size at the Knelson concentrator - the heavy processing fraction at the Knelson concentrator is sent for further gold processing, and the tailings are sent to the intermediate product PP-3 for processing by the bacterial-chemical vat block 49-59.

 Block 49-59 for PP-3 and total tails 49, consists of a conveyor 50, a crusher 51, a tank for heating hot water 52 and a pump 53. A pump for hot water 53 circulates hot water in water jackets that heat eight sections of the leach vat (54-1) - (54-8). On eight sections of the leach vat, one vat for clarifying solution 55 and two vats for precipitating gold (56-1) to (56-2) are installed. The spent solution enters the dehydrated solution tank 57, filter 58 is carried out, the solution is backed up with cyanide and pumped with the solution pump 59 to leach (54-1) - (54-8), block 49-59.

 The cost of combined processing of copper-pyritic ores and dump products in the northern regions of the Urals and Siberia is 2.5-4.0 times lower than the processing of copper-pyritic ores, dump products, and also stagnant concentrates in the traditional way.

 The heavy fraction 32, 37, 42, 47, 56-1, 56-2 are summarized in block 60 and sent for further processing. The tailings 38, 43, 48 are summarized in block 49 and sent to block 49-59 for a bacterial-chemical vat leaching with a heated bacterial solution for the northern and central regions of the Urals and Siberia. The tailings of block 58 are sent to block 61.

Example
As an example, consider copper-pyritic deposits: Valentorskoye, Kaluginskoye, Mednogorskoye, Nikolaev-Kolyuschenskoye, Aleksandrovskoye, III International, Molodezhnoye, Makinskoye, Gayskoye (3rd deposit). The geochemical spectrum of related elements is represented by Cu, Te, Ag, Pb, Zn, Sb, Bi. Clarks of gold concentration (average values) for pyrite-chalcopyrite ores are 300-350, for pyrite-chalcopyrite-sphalerite ores - 380-430.

 For the pyrite copper-pyritic ores of these deposits, the linear correlation coefficients of gold and related elements: Au-Ag, Au-Cu, Au-As, Au-Se, Au-Te, Au-Sb, Au-Bi are respectively equal to - 0 , 56; 0.25; 0.51; 0.27; 0.44; 0.01; 0.13. For massive pyrite-chalcopyrite pyrite ores of these deposits, the linear correlation coefficients between gold and related elements: Au-Cu, Au-Zn, Au-Pb, Au-Ag, Au-As, Au-Bi are respectively equal - 0.79; 0.28; 0.46, 0.36; 0.21; 0.31. For the incorporation of pyrite-chalcopyrite ores of these deposits, linear correlation coefficients between gold and related elements: Au-Cu, Au-Zn, Au-Ag, Au-As, Au-Se, Au-Te, Au-Sb, Au-F , Au-S - respectively equal - 0.49; 0.28; 0.57; 0.34; 0.35; 0.75; 0.16; 0.34; 0.44. For massive pyrite-chalcopyrite-sphalerite ores of these deposits, linear correlation coefficients of gold and related elements: Au-Cu, Au-Zn, Au-Pb, Au-Ag, Au-As, Au-Se, Au-Sb, Au- Bi - respectively equal - 0.52; 0.58; 0.68; 0.83; 0.23; 0.20; 0.06; 0.3. For disseminated pyrite-chalcopyrite-sphalerite ores of these deposits, linear correlation coefficients between gold and related elements: Au-Cu, Au-Zn, Au-Ag, Au-Ag, Au-Pb, Au-As, Au-Te, Au- Sb, Au-Bi, Au-Be - respectively equal - 0.71; 0.18; 0.14; 0.8; 0.38; 0.5; 0.57; 0.42; 0.02.

 In pyrite ores, gold is found in pyrite and arsenopyrite. In pyrite-chalcopyrite and pyrite-chalcopyrite-sphalarite ores, gold is found in chalcopyrite. The zones of maximum gold accumulation in copper-pyrite deposits are disseminated pyrite-chalcopyrite-sphalerite ores, the off-balance areas of which can be industrialized for gold, especially in places where rupture of tectonic structures is manifested.

 The contrast of ores and the X-ray radiometric concentration of copper-pyritic ores of these deposits were studied by geological and technological mapping by contouring individual small ore blocks with the selection of ore varieties and then determining the contrast index for each ore grade. Predicted indicators of contrast and ore concentration are determined for massive pyrite-chalcopyrite and pyrite-chalcopyrite-sphalerite ores. All forecast calculations of contrast and concentration for copper-pyritic ores were performed according to core and furrow tests, as well as well logging for exploratory drilling of the considered deposits.

 The averaged contrast indicators and technological indicators of finely proportioned (10-20 kg) X-ray radiometric sorting of copper-pyrite ores are given in the table.

Conditional: P _max - an indicator of contrast according to Pukhalsky
M - Mokrousov contrast modulus
B-1 - the maximum possible practical indicators, when the mixing indicator K _per = 1.15.

B-2 - the minimum possible practical indicators, when the mixing indicator K _per = 1.20.

For copper-pyrite ores of deposits: Valentorskoye, Mednogorskoye, Molodezhnoye it is established - copper-pyrite ores belong to the technological type of medium-contrast ores with contrast ratios (P _max ) equal to 1.14-1.19, and practical outputs of tailings for В-1 - 25.0-26.0%, for B-2 -19.2-19.4% and radiometric concentration factors for B-1 -1.28-1.29, for B-2 -1.15-1, 16;
For copper-pyrite ores of deposits: International, Kaluginskoye, Nikolaev-Kolyuchenskoye, Makinskoye, Gayskoye (3rd deposit), it was established that copper-pyrite ores belong to the technological type of high-contrast ores with contrast ratios (P _max ) of 1.31-1 , 40, with practical yields of tailings for В-1 -31.0-44.0%, for В-2 -23.0-38.0% and X-ray radiometric enrichment factors for В-1 -1.41-1.66 for B-2 -1.36-1.58.

 In the combined method of processing waste products from technogenic copper-pyrite deposits, the boundary content can be increased to λ / α equal to 1.6-1.8 (where λ is the boundary gold content, α is the average gold content in the dump products). At boundary contents, when the value of λ / α is 1.6-1.8, the enrichment coefficient of the X-ray radiometric sorting of B-1 and B-2 increases by 50-65%. A combined method for processing technogenic deposits of copper-pyritic ores is implemented with the aim of increasing the extraction of gold by 2.1-2.6 times and the inclusion of poor copper-pyritic ores with gold content of 0.3-1.0 g / t in processing.

 Thus, it was established that copper-pyrite ores of deposits: Valentorskoye, Mednogorskoye, Molodezhnoye should be attributed to the technological type of medium-contrast ores, and ore from deposits: International, Kaluginskoye, Nikolaevo-Kolyuschenskoye, Makinskoye, Gayskoye (3rd deposit) - should be attributed to technological type of high-contrast ores with a coefficient of x-ray radiometric concentration of ores of 1.41-1.66. This allows you to significantly increase the extraction of gold from marketable ores and further involve significant amounts of poor balance and off-balance ores and dump products, as well as stagnant concentrates, in the development.

 The economic effect of the proposed technical solution increases significantly when copper-pyrite and pyrite-polymetallic ores, dump products, as well as stale concentrates of deposits located in the vicinity of gas fields developed by RAO Gazprom are processed.

 The processing of old dumps of copper-pyrite and pyrite-polymetallic ores and stagnant concentrates according to the proposed technical solution in the regions of the Urals and Siberia can significantly improve the ecological environment, since poor and off-balance copper-pyrite ores and dump products will not be stored, but will be processed. and this will allow ecologically rehabilitating large areas of the north of the Urals and Siberia.

Claims (8)

 1. A combined method for the extraction of gold in the processing of copper-pyritic ores and waste products from ores located in the North, including the transportation of ores, their rapid analysis by X-ray radiometric method, regulation of the boundary content of the product by X-ray radiometric sorting and separation, using, as parameters, characterizing the features of the geochemistry of gold, clarke concentrations of copper, tellurium, silver, zinc and other elements, characterized in that they implement x-ray radiometric Large-scale sorting and piecewise separation, divide the ore into five products - enriched products with a gold content of more than 2.5 - 4.0 g / t, which are sent for processing to extract gold, an intermediate product PP-1 with a gold content of 1.8 - 2.5 or 2.2 - 4.0 g / t, which is in native form or in the form of tellurides, an intermediate product of PP-2 with a gold content of 1.1 - 1.8 or 1.3 - 2.2 g / t, which is in intergrowths with sulfides, the intermediate product PP-3 with a gold content of 0.15 - 1.1 or 0.15 - 1.3 g / t and dump tailings with a gold content of less than 0.15 g / t, which is sent to the dump, for each of the PP-1 and PP-2 products, one or two processing operations are carried out at a Knelson concentrator, the resulting heavy fraction is sent to gold processing, and the tailings are sent to the intermediate PP-3 product for bacterial chemical leaching, which in the winter, autumn and spring, is carried out with heating of the bacterial solution, they intensify the activity of bacteria of the bacterial chemical leaching and regulate the volume PP-1, PP-2, PP-3, enriched products and tailings using a microcomputer, determine the gold content in the portions of the tailings, while the portions of the tailings are returned to the inlet to the piece separator if the gold content in the portions of the tailings is higher the optimal gold content in the tailings of the processing plants, determine the gold content in the tailings of the separation after the return of the portions, the information obtained is used to control and regulate the processes.  2. The method according to claim 1, characterized in that they combine in geochemical samples for the main types of ores deposits of ores homogeneous in mineral composition, using clarks of its concentrations that reflect the degree of gold accumulation in ores as parameters characterizing the features of gold geochemistry, the accumulation coefficient of gold for the pyrite formation is determined as the weighted average by the number of deposits in each type of ore, the zones of maximum gold accumulation in copper-pyrite deposits establish off-balance Lots of disseminated pyrite-chalcopyrite-sphalerite ore. 3. The method according to claim 1, characterized in that x-ray radiometric sorting and separation are implemented by using as a criterion for the separation of ores the product of the analytical parameters of the indicator elements of copper, tellurium, silver, lead, zinc, antimony, bismuth, while the criterion for the separation of copper pyrite ores are determined by the expression

where N _Cui are the intensities of the characteristic X-ray radiation (XRD) of the copper recorded by each detector of the relay separator in the energy range of 7.8 - 8.2 keV;
N _S1i — scattered radiation intensities of Plutonium-238 sources recorded in the energy range 13.4 - 16.8 keV;
N _Tei are the HRI intensities of tellurium recorded in the energy range of 27.2 - 27.5 keV;
N _S2i — scattered radiation intensities of Americium-241 sources recorded in the energy range _48–56 keV;
N _Agi — silver CRI intensities recorded in the energy range of 22.0 keV;
N _S3i — scattered radiation intensities of Americium-241 sources recorded in the energy range 48.0–59.0 keV;
N _Pbi - lead CRI intensities recorded in the energy range of 11.5 - 13.0 keV;
N _S4i are the intensities of the scattered radiation of Cadmium-109 sources recorded in the energy range of 19.0 - 21.5 keV;
N _Zni — intensities of CRI of zinc recorded in the energy range of 8.4–8.8 keV;
N _S5i are the intensities of the scattered radiation of Cadmium-109 sources recorded in the energy range of 19.0 - 21.5 keV;
N _Sbi — antimony CRI intensities recorded in the energy range of 26.1 - 26.5 keV;
N _S6i — scattered radiation intensities of Americium-241 sources recorded in the energy range 48.0–59.0 keV;
N _Bii — bismuth CRI intensities recorded in the energy range of 10.5 - 10.9 keV;
N _S7i are the intensities of the scattered radiation of Cadmium-109 sources recorded in the energy range of 19.0 - 21.5 keV;
n is the number of x-ray radiometric detectors of the relay separator.  4. The method according to claim 1, characterized in that they realize one or two processing operations of PP-1 at a Knelson concentrator, while the product PP-1 with a particle size of -5 + 0 mm is first sent to screening, the obtained ore mass is + 2.0 mm subjected to grinding, and a particle size of -2.0 mm is sent to the first operation on a Knelson concentrator, at a particle size of more than +0.1 mm the PP-1 product is subjected to grinding, and at a particle size of -0.1 mm, it is directed to a second operation on a Knelson concentrator, obtained at the Knelson concentrator, the heavy fraction is sent for processing in gold and tails directed into PP-3 to bacterially-chemical vat leaching.  5. The method according to claim 1, characterized in that they carry out one or two processing operations of PP-2 at a Knelson concentrator, while with a fineness of copper-pyrite ores PP-2 less than -0.08 mm, the first processing operation of PP-2 is carried out on a Knelson concentrator, and at a particle size of more than +0.08 mm PP-2 is subjected to grinding, the ore mass of PP-2 with a grain size of -0.06 mm is sent to the second processing operation of PP-2 at a Knelson concentrator, and the ore mass of PP-2 with a grain size of +0 , 06 mm is subjected to grinding, the heavy fraction obtained at the concentrator is directed to erabotku gold, and their tails directed to PP-3 to bacterially-chemical vat leaching.  6. The method according to p. 1, characterized in that the geological and technological mapping of the ore deposit or waste dumps with the determination of the spatial variability of the optimal size of native gold grains is carried out, when studying the spatial variability of the optimal size of native gold grains, the studied ore deposit or old, dead dumps are divided into separate small ore blocks and in each of them determine the optimal size of native gold grains, realize the processing of ores of individual small ore blocks at the Knelso concentrator according to the obtained optimum fineness of native gold grains in each ore block.  7. The method according to p. 1, characterized in that PP-3 is directed to a bacterial-chemical vat leaching with heating of the bacterial solution in the winter and autumn-spring periods when using a tank for heating hot water and a pump for circulating hot water in water jackets, eight sections of the leach tank are heated, one tank for clarification of the solution, two sections of the gold precipitation tank and the waste solution tank, the spent solution is reinforced with cyanide and pumped to the leach vanie. 8. The method according to claim 1, characterized in that the heating of the solutions in the sections of the leach vat, in the vat for clarification of the solution and the deposition of gold, as well as the reservoir for spent solutions is carried out using double walls - water vats shirts, with a distance between the walls 3 - 7 cm, hot water is continuously pumped through the water jacket, heated in the tank and supplied to the shirts using a pump, and in frosts below -20 ^o C in the vats section for leaching, clarifying the solution and precipitating gold for additional heating of the solution Portable batteries are installed through which hot water is continuously pumped.

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