RU2165792C2 - Integrated method for recovering platinum and palladium metals in the processing of copper-nickel sulfide ores and rejected products - Google Patents

Abstract

FIELD: mining industry and precious metal technologies. SUBSTANCE: 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 platinum and palladium metals: enriched product, three intermediate products, and nonutilizable waste. Enriched product is processed to recovery platinum and palladium metals. The first intermediate product is subjected to one or two processing operations of Knelson concentrator and the second one is processed one to four 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, 2 tbl

Description

 The invention relates to a technology for the concentration and processing of sulfide copper-nickel ores and waste products in the recovery of platinum-palladium metals. These ores are part of segregation deposits located in the northern regions of the Kola Peninsula, the Urals and Siberia. A group of platinum minerals combines platinum and five elements similar to it - palladium (Pd), irridium (Jr), rhodium (Rh), osmium (OS), ruthenium (Ru).

 A combined method of processing copper ores is known, including transportation of ores, their rapid analysis by radiometric methods, averaging of ore quality, heap bacterial-chemical leaching and intensification of bacterial activity (RF Patent N 20551748 C1, B 03 B 7/00, 01/10/1996).

 The disadvantage of this method is the inability to use heap bacterial-chemical leaching at low temperatures in the winter.

 The closest analogue to the proposed method is a combined method for the extraction of platinum-palladium metals in the processing of sulfide copper-nickel ores and waste products from ore from deposits located in the northern regions of the Kola Peninsula, the Urals and Siberia, including ore transportation, express analysis by X-ray radiometric method, and regulation of the boundary value the content of the product of x-ray radiometric sorting and separation, the use of patterns of accumulation of platinum-palladium meth llov simultaneously with copper, nickel, cobalt, tin, lead and other elements (Abramov A.A. et al. "Enrichment of non-ferrous metal ores", M., Nedra, 1991, pp. 7, 21-22, 52-53, 57, 315-345).

 The disadvantage of this method is the impossibility of the complete extraction of platinum-palladium metals from sulfide copper-nickel ores, as well as the impossibility of processing significant volumes of poor balance and off-balance ores of dump products and stagnant concentrates.

 At present, very large volumes of platinum-palladium metals have accumulated in the wastes of mining and metallurgical industries (tailings for enrichment and metallurgy, stale concentrates, other dump products) during the processing of sulfide copper-nickel ores. In some deposits, the cost of platinum-palladium metals in sulfide copper-nickel ores is commensurate with the cost of copper and nickel. Extraction of platinum-palladium metals in passing, the degree of extraction of platinum-palladium metals does not exceed 30-50%.

 The aim of the claimed invention is to increase the efficiency of extraction of platinum-palladium metals from ores, as well as the involvement in the processing of a significant amount of poor balance and off-balance ores, dump products and stale concentrates, to improve the environment in the North of the Kola Peninsula, the Urals and Siberia.

 This goal is achieved by the fact that in the combined method for the extraction of platinum-palladium metals from sulfide copper-nickel ores and waste products from ore from deposits located in the northern regions of the Kola Peninsula, the Urals and Siberia, including ore transportation, express analysis by x-ray radiometric method, regulation of the boundary content product of X-ray radiometric sorting and separation, using patterns of accumulation of platinum-palladium metals simultaneously with copper, nickel ore, cobalt, tin, lead and other elements, are carried out using x-ray large-size sorting and lump separation, the separation of the ore mass of copper-nickel ores into five products: enriched products containing platinum-palladium metals more than 4.0-12.0 g / t, which are sent for further processing, intermediate products PP-1 with a platinum-palladium metal content of 2.5-4.0 g / t or 5.6-12.0 g / t, PP-2 with a platinum-palladium metal content of 1.7-2, 5 g / t or 2.8-5.6 g / t, PP-3 with platinum-palladium content metals 0.1-1.7 g / t or 0.1-2.8 g / t and dump tailings with a platinum-palladium metal content of less than 0.10 g / t, which are sent to the dump, an intermediate product of PP-1, containing significant part of the platinum-palladium metals in free form is subjected to one or two processing operations at a Knelson concentrator, the intermediate product PP-2, containing a significant part of platinum-palladium metals in intergrowths with sulfides, is subjected to one to four processing operations at a Knelson concentrator, the intermediate product PP-3 is sent tons for bacterial chemical leaching, which in the winter, autumn and spring, is carried out with the bacterial solution heated, the heavy fraction obtained at the Knelson concentrator is sent to the further processing of platinum-palladium metals, and the obtained tails are sent to the intermediate product PP-3, they intensify the activity of bacteria of bacterial chemical leaching and regulate the volumes of intermediate products PP-1, PP-2, PP-3 using a microcomputer.

 In addition, the goal is achieved in that the rock mass PP-1 of sulfide copper-nickel ores with a grain size of 5 + 0 mm is sent for screening, the ore mass with a grain size of +2 mm is subjected to grinding, the mass with a grain size of -2 mm is sent to the first PP-processing operation 1 at a Knelson concentrator, a heavy fraction and a product for re-screening are isolated, after which the ore mass with a size of more than +0.1 mm is subjected to additional grinding, and the ore mass with a size of less than 0.1 mm is subjected to a second processing operation of PP- 1 at a Knelson concentrator, during the processing of which a heavy fraction is allocated that is sent for further processing, and tails that are sent to the intermediate product PP-3.

 The goal is also achieved by the fact that PP-2 is screened, the resulting rock mass with a particle size of more than +0.08 mm is subjected to grinding, a particle size of less than -0.08 mm is subjected to the first processing step of PP-2 at a Knelson concentrator, the ore mass of PP-2 with a grain size of + 0.06 mm is subjected to additional grinding, at a particle size of -0.06 mm, the second processing step of PP-2 is carried out at a Knelson concentrator, the ore mass of PP-2 with a grain size of more than + 0.04 mm is subjected to additional grinding, with a particle size of less than -0.04 mm third operation perer PP-2 operations at a Knelson concentrator, in which a heavy fraction and a product for re-screening are isolated, after which the ore mass with a grain size of more than + 0.02 mm is subjected to the fourth processing step of PP-2 at a Knelson concentrator, the heavy fractions obtained at Knelson concentrators are sent for further processing of platinum-palladium metals, and the tailings are sent to the intermediate product PP-3 for processing by the bacterial chemical vat.

 In addition, the goal is achieved by the fact that to determine the contrast and x-ray ore dressability of the ores, geological and technological mapping of the processed ores and dump products is carried out with the spatial variability of the optimal grain size of platinum-palladium metals being determined, while the studied ore deposit or old dead dumps are divided into separate small ore blocks and each of them determines the optimal grain size of platinum-palladium metals.

 The mining mass of the intermediate product PP-3 is directed to a bacterial-chemical vat leaching with a heating of the bacterial solution in the winter and autumn-spring periods, circulation of hot water in water jackets that heat eight sections of the leaching vat, one vat for clarifying the solution, two vat for deposition of platinum-palladium metals and a reservoir for spent solutions is carried out using a tank for heating hot water and a pump.

The bacterial solution is heated in the vat sections for leaching, clarification of the solution and precipitation of platinum-palladium metals and the spent solution tank in the winter, autumn and spring periods using double walls - water chambers for leaching, clarification of the solution and precipitation of platinum-palladium metals, with a distance between double walls of 3-7 cm, which is filled with a water jacket, through which hot water is continuously pumped using a pump, heated in a special tank, with pain In freezing temperatures of -20-35 ^o C, portable batteries are installed in the tank section for leaching, clarifying the solution and precipitating platinum-palladium metals to heat the bacterial solution, hot water is continuously pumped through the portable batteries and the bacterial solution is additionally heated in winter at temperatures below -20- 35 ^o C. In order to realize the heating of the bacterial solution and the circulation of hot water through the water shirts of the vat sections, the walls of the vat sections for leaching, the vat for clarifying the solution, vat For the deposition of platinum-palladium metals, they are made of acid-resistant steel.

The temperature of hot water in the autumn-spring and winter periods is regulated using an automatic machine that takes into account the temperature of the solution and the temperature of the environment to ensure a constant temperature of the solution + 28-30 ^o C.

где: Ncu_i - интенсивности характеристического рентгеновского излучения (ХРИ) меди, зарегистрированные каждым детектором эстафетного сепаратора в энергетическом диапазоне 7,8-8,2 КэВ;
Ns₁i - интенсивности рассеянного излучения источников Плутония-238, зарегистрированные в энергетическом диапазоне 13,6-16,8 КэВ;
N_Nii - интенсивности ХРИ никеля, зарегистрированные в энергетическом диапазоне 7,1-7,7 КэВ;
Ns₂i - интенсивности рассеянного излучения источников Кадмий-109, зарегистрированного в энергетическом диапазоне 19,0-21,5 КэВ;
Ncoi - интенсивности ХРИ кобальта, зарегистрированные в энергетическом диапазоне 6,7-7,1 КэВ;
Ns₃i - интенсивности рассеянного излучения источников Кадмия-109, зарегистрированные в энергетическом диапазоне 19,0- 21,5 КэВ;
Nsni - интенсивности ХРИ олова, зарегистрированные в энергетическом диапазоне 25,0-25,4 КэВ;
Ns₄i - интенсивности рассеянного излучения источников Америций-241, зарегистрированные в энергетическом диапазоне 48,0-59,0 КэВ;
Npbi - интенсивности ХРИ свинца, зарегистрированные в энергетическом диапазоне 11,5-13,0 КэВ;
Ns₅i - интенсивности рассеянного излучения источников Кадмий-109, зарегистрированные в энергетическом диапазоне 19,0-21,5 КэВ;
NBii - интенсивности ХРИ висмута, зарегистрированные в энергетическом диапазоне 10,5-10,9 КэВ;
Ns₆i - интенсивности рассеянного излучения источников Кадмий-109, зарегистрированные в энергетическом диапазоне 19,0-21,5 КэВ;
NAsi - интенсивности ХРИ мышьяка, зарегистрированные в энергетическом диапазоне 9,5-11,5 КэВ;
Ns₇i - интенсивности рассеянного излучения источников Кадмий-109, зарегистрированного в энергетическом диапазоне 19,0- 21,5 КэВ;
Nsbi - интенсивности ХРИ сурьмы, зарегистрированные в энергетическом диапазоне 26,1-26,5 КэВ;
Ns₈i - интенсивности рассеянного излучения источников Америций-241, зарегистрированные в энергетическом диапазоне 48-59,0 КэВ.To increase the sensitivity and selectivity of X-ray radiometric sorting and separation of sulfide copper-nickel ores, the products of the analytical parameters of indicator elements Cu, Ni, Co, Sn, Pb, Bi, As, Sb are used as a criterion for the separation of ores, while the criterion for the separation of sulfide copper-nickel ore is determined by the expression:

where: Ncu _i 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;
Ns ₁ i are the intensities of the scattered radiation of Plutonium-238 sources recorded in the energy range of 13.6-16.8 KeV;
N _Nii — CRI intensities of nickel recorded in the energy range of 7.1–7.7 keV;
Ns ₂ i are the intensities of the scattered radiation of Cadmium-109 sources recorded in the energy range of 19.0-21.5 KeV;
Ncoi — intensities of the CRI of cobalt recorded in the energy range of 6.7–7.1 keV;
Ns ₃ i are the intensities of the scattered radiation of Cadmium-109 sources, recorded in the energy range of 19.0-21.5 KeV;
Nsni — tin HRI intensities recorded in the energy range of 25.0–25.4 keV;
Ns ₄ i are the intensities of the scattered radiation of Americium-241 sources recorded in the energy range of 48.0-59.0 KeV;
Npbi — lead CRI intensities recorded in the energy range of 11.5–13.0 keV;
Ns ₅ i are the intensities of the scattered radiation of cadmium-109 sources recorded in the energy range of 19.0-21.5 keV;
NBii — bismuth CRI intensities recorded in the energy range of 10.5–10.9 keV;
Ns ₆ i are the intensities of the scattered radiation of Cadmium-109 sources recorded in the energy range of 19.0-21.5 KeV;
NAsi — arsenic HRI intensities recorded in the energy range of 9.5–11.5 keV;
Ns ₇ i are the intensities of the scattered radiation of Cadmium-109 sources, recorded in the energy range of 19.0-21.5 KeV;
Nsbi — antimony CRI intensities recorded in the energy range of 26.1–26.5 keV;
Ns ₈ i are the intensities of the scattered radiation of Americium-241 sources recorded in the energy range 48–59.0 keV.

 In the Far North, operations are introduced to regulate the volume and weighted average content of platinum-palladium metal of the ore mass of intermediate products PP-1, PP-2, PP-3 and enriched OP products to reduce the volumes of intermediate products PP-1, PP-2, PP- in winter 3 and their increase in the autumn-winter periods.

 In FIG. 1 is a flow chart of the combined processing of sulfide copper-nickel ores and dump products in the extraction of platinum-paladium metals in the northern regions.

 The initial sulfide copper-nickel ore with a particle size of less than 500 mm (-500) 1 is screened 2 in order to isolate the ore mass larger than 300 mm (+300), the ore +300 is crushed 3 and sent to large-portion x-ray radiometric sorting of trolleys 4, where platinum-palladium correlation is used metals with elements of Cu, Ni, Co, Sn, Pb, As, Sb. Using an ore control station (RCC) 5, large-batch sorting separates the rock mass into a number of products: rich copper-nickel ore with high contents of platinum-palladium metals 6, ordinary ore 7, poor ore (PP-1) 8, off-balance copper-nickel ores ( PP-2) 9, off-balance low-grade ores (PP-2) 10 and dump tailings 11. Rich platinum-palladium ore with a platinum content of more than 4-12 g / t (total) and higher without piecewise separation is sent to the ore quality averaging block 12. Ordinary copper-nickel ore with ordinary grade platinum-palladium metals are sent to piecewise separation. After screening 13 and crushing +150 mm 14, washing 15 and removing with drying and thickening the slag 16, they are 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 of fineness class -200 + 80 mm (21, fineness class -80 + 50 mm (22), fineness class -50 + 30 mm (23) with separation of separation products into tailings 24 and concentrate 25. The dump tailings of lump separation after averaging the quality of ores 26 are sent to the separation dump 27, and the concentrate is sent to the quality averaging block 12. Enriched ore and ore concentrate pokuskovoy separation tested quality ores averaging operation 12 and is sent to product enriched product hopper 28, from which is sent to further processing 70 platinopalladievyh metals.

 After X-ray radiometric sorting of the trolleys, where correlation bonds of platinum-palladium metals with elements - indicators Cu, Ni, Co, Sn, Pb, As, Sb are used, the intermediate product PP-1 is sent to block 29-58 (Fig. 1) of centrifugal concentration (Knelson concentrator ), the rock mass PP-1 with a grain size of -5 + 0 mm is screened 29. The resulting sub-sieve product with a grain size of + 2 mm is subjected to grinding 30, and the sub-sieve is sent to the first processing operation at a Knelson concentrator 31, where it isolates concentrate 32 and product 33 for repeated screening 34, after which the ore mass with a size of less than -0.1 mm (35) is subjected to a second processing operation at a Knelson concentrator 36, and the ore mass of PP-1 with a grain size of more than + 0.1 mm 36 is subjected to additional grinding 35. In the second operation on a concentrator Knelson 36 isolate the heavy fraction 37 and tails 38. The heavy fraction 32 and 37 are sent for further processing of platinum-palladium metals, and the tails 38 are sent to PP-3 for processing by a bacterial chemical tank.

 The ore mass PP-2 with a grain size of less than -0.08 mm is screened, the obtained fraction is sent to the first processing operation at a Knelson concentrator 41, and the ore mass PP-2 with a grain size greater than + 0.08 mm is subjected to grinding 40. The light fraction obtained at a Knelson concentrator sent for re-screening 44, and with fineness of less than -0.06 mm subjected to a second processing operation on a Knelson concentrator 46. The ore mass PP-2 with a grain size of more than + 0.06 mm is subjected to additional grinding 45. The second operation for concentrating Ore Knelsona allocates heavy fraction tails 47 and 48. The heavy fraction 47 is sent to further processing platinopalladievyh metals, and tails 48 is directed to screening 49.

 Obtained after screening 49, the PP-2 ore mass with a size of less than -0.04 mm is subjected to a third processing operation at a Knelson concentrator 51, and the PP-2 ore mass with a grain size of more than + 0.04 mm is subjected to additional grinding 50. The third operation at a Knelson concentrator emits a heavy fraction 52 and tails 53. The heavy fraction 52 is sent to the traditional processing of platinum-palladium metals, and the tails 53 are sent to re-screen 54 and, when the size of the ore mass PP-2 is less than -0.02 mm, they are subjected to the fourth grinding operation swellings at a Knelson concentrator 56, and a mass of PP-2 with a particle size of more than + 0.02 mm is subjected to additional grinding 55. The fourth operation at a Knelson concentrator emits a heavy fraction 57 and tails 58. A heavy fraction 57 is sent for further processing of platinum-palladium metals, and tails 58 are sent for processing vat bacterial-chemical method, block 29-58 (Fig. 1).

 Block 59-69 (Fig. 1) consists of the following components: a tank for PP-3 and total tails 59, a conveyor 60, a crusher 61, a tank for heating hot water 62 and a pump 63. The pump 63 circulates the hot water of the water jackets, which heat eight sections of the leach vat (64-1) - (64-8). On eight sections of the leach vat, one vat for clarifying solution 65 and two vats for precipitating platinum-palladium metals (66-1) - (66-2) are installed. The spent solution enters the reservoir 67 for free solution, filtering 68 is realized and the solution is pumped using a pump to pump solution 69 to leach (64-1) - (64-8) (Fig. 1).

 The heavy fraction of platinum-palladium metals 28, 37, 47, 57, 66-1, 66-8 (Fig. 1) is summarized in block 70 and sent for further processing. The tailings 38, 43, 48, 53, 58 are summarized in block 59 and sent to block 59-69 (FIG. 1) for a bacterial-chemical vat leaching with a heated bacterial solution for the northern regions. The filter tailings 68 are sent to block 71 (FIG. 1).

 Example 1. As an example, consider sulfide copper-nickel ore deposits Talnakhskoye and October. The geochemical spectrum of related elements is represented by Cu, Ni, Co, Sn, Pb, As, Sb.

 Clark concentration of platinum-palladium metals for the Talnakh deposit is 1446, for the Oktyabrsky deposit - 672.

 The platinum group metal contents for the Talnakhskoye and Oktyabrskoye deposits are shown in Table 1.

 For sulfide copper-nickel ores of the Talnakh deposit, the correlation coefficients between platinum and related elements: Pt-Cu, Pt-Ni, Pt-Co, Pt-Sn, Pt-Pb, Pt-Bi, Pt-As, Pt-Sb are respectively equal - 0.78, 0.56, 0.52, 0.36, 0.32, 0.24, 0.51, 0.21. The correlation coefficients between palladium and related elements: Pd-Cu, Pd-Ni, Pd-Co, Pd-Sn, Pd-Pb, Pd-Bi, Pd-As, Pd-Sb, respectively, are 0.38, 0.68 0.62, 0.38, 0.34, 0.21, 0.76, 0.24.

 For the sulfide copper-nickel ores of the Oktyabrsky deposit, the correlation coefficients between platinum and related elements: Pt-Cu, Pt-Ni, Pt-Co, Pt-Sn, Pt-Pb, Pt-Bi, Pt-As, Pt-Sb, respectively, are equal - 0.71, 9.52, 0.48, 0.32, 0.28, 0.21, 0.47, 0.18. For the Oktyabrsky deposit, the correlation coefficients between palladium and related elements: Pd-Cu, Pd-Ni, Pd-Co, Pd-Sn, Pd-Pd, Pd-Bi, Pd-As, Pd-Sb, respectively, are 0.79, 0.63, 0.59, 0.32, 0.29, 0.18, 0.71, 0.19.

 For the Talnakhskoye field, the correlation coefficients between platinum, palladium and related elements are slightly higher than for the Oktyabrskoye field. For the Talnakh and Oktyabrsk deposits, stable correlations were established between Pt, Pd and copper, nickel, cobalt, less stable bonds were established between Pt, Pd and tin and lead. Thus, it was found that sulfide copper-nickel ores, waste products and stale concentrates can be successfully processed by x-ray radiometric sorting and separation during the recovery of platinum-palladium metals.

 Ore contrast and X-ray concentration of sulfide copper-nickel ores were studied by geological and technological mapping by contouring individual small ore blocks with the selection of ore grades and then determining the contrast index for each ore grade. All forecast calculations of contrast and concentration for sulfide copper-nickel ores were performed according to core and furrow testing of the deposits under consideration.

 The averaged contrast indicators and technological indicators of finely proportioned (10-20 mg) X-ray radiometric sorting of sulfide copper-nickel ores are shown in Table 2.

Copper-nickel ores of the Talnakhskoye deposit are of the technological type of high-contrast ores with a contrast ratio (P _max ) of 1.38 and X-ray radiometric concentration factors, for B-1 equal to 1.62, and for B-2 equal to 1.54.

Copper-nickel ores of the Oktyabrsky deposit are of the technological type of medium-contrast ores with a contrast ratio (P _max ) of 1.12 and X-ray radiometric concentration factors, for B-1 equal to 1.24, and for B-2 equal to 1.14.

 With the combined method of processing waste products and technogenic copper-nickel deposits, the sorting boundary content can be increased to 1.6-1.8. In this case, the enrichment coefficient of the X-ray radiometric sorting of B-1 and B-2 will increase by 50-62%. A combined method for processing technogenic copper-nickel products and stagnant concentrates is implemented to increase the extraction of platinum-palladium metals by 2.2-2.4 times and to involve poor platinum-palladium ores in the processing.

 Thus, stable correlations between Pt, Pd and Cu, Ni, Co, Sn, Pb have been established for sulfide copper-nickel ores of the Talnakh and Oktyabrsky deposits, and X-ray radiometric sorting and separation can be successfully used to extract platinum-palladium metals. The Talnakhskoye deposit should be attributed to the technological type of high-contrast ores with coefficients of x-ray radiometric concentration of 1.54-1.62. This will significantly increase the extraction of platinum-palladium metals and additionally involve significant volumes of lean balance and off-balance ores of dump products, as well as stale concentrates, in processing. It was established that the content of platinum-palladium metals in stagnant magnetite concentrates reaches 25-39 g / t in terms of (total). Using a Knelson concentrator in one operation, the extraction of Pt and Pd from this material reaches 40%. Sorting and separation provide the extraction of 80-90% of Pt and Pd. The tank method provides recovery of 85-95% of Pt and Pd. The weighted average recovery of Pt and Pd by the combined method will be 82%.

 The processing of old dumps of sulfide copper-nickel ores, as well as stale concentrates according to the proposed technical solution in the northern regions, can significantly improve the ecological environment, since poor and off-balance sulfide copper-nickel ores, dump products and stagnant concentrates will not be stored, but will be processed , and this will allow environmentally rehabilitating large areas of the North of the Kola Peninsula, the Urals and Siberia.

 Thus, the proposed technical solution is industrially applicable and cost-effective.

Claims (8)

 1. A combined method for the extraction of platinum-palladium metals in the processing of sulfide copper-nickel ores and waste products from ore from deposits located in the northern regions of the Kola Peninsula, the Urals and Siberia, including ore transportation, express analysis by X-ray radiometric method, regulation of the boundary content of the product of X-ray radiometric sorting and separation, using patterns of accumulation of platinum-palladium metals simultaneously with copper, nickel, cobalt, tin, pig and other elements, characterized in that, using x-ray large-size sorting and lump separation, the ore mass of copper-nickel ores is divided into five products: enriched products containing platinum-palladium metals more than 4.0 - 12.0 g / t, which are sent for further processing, intermediate products PP-1 with a content of platinum-palladium metals 2.5 - 4.0 or 5.6 - 12.0 g / t, PP-2 with a content of platinum-palladium metals 1.7 - 2.5 or 2.8 - 5 , 6 g / t, PP-3 with a content of platinum-palladium metals of 0.1 - 1.7 silt and 0.1 - 2.8 g / t and tailings with a platinum-palladium metal content of less than 0.10 g / t, which are sent to the dump, the intermediate product PP-1, containing a significant part of the platinum-palladium metals in free form, is pulled by one or two processing operations at a Knelson concentrator, the intermediate product PP-2, containing a significant portion of the platinum-palladium metals in intergrowths with sulfides, is subjected to one to four processing operations at a Knelson concentrator, the intermediate product PP-3 is sent to a tank bacterium chemical-chemical leaching, which is carried out in the winter, autumn-spring periods with heating of the bacterial solution, the heavy fraction obtained at the Knelson concentrator is sent to the further processing of platinum-palladium metals, and the resulting tails are sent to the intermediate product PP-3, they intensify the activity of bacterial vat bacteria chemical leaching and regulate the volumes of intermediate products PP-1, PP-2, PP-3 using a microcomputer.  2. The method according to p. 1, characterized in that the rock mass PP-1 of sulfide copper-nickel ores with a grain size of -5 + 0 mm is sent for screening, the ore mass with a grain size of +2 mm is subjected to grinding, the mass with a grain size of -2 mm is sent to the first operation of processing PP-1 at a Knelson concentrator, a heavy fraction and a product for re-screening are isolated, after which the ore mass with a particle size of more than +0.1 mm is subjected to additional grinding, and the ore mass with a particle size of less than 0.1 mm is subjected to a second processing operation of PP-1 for a concentrator The Knelson torus, during processing of which a heavy fraction is allocated, which is sent for further processing, and tails, which are sent to the intermediate product PP-3.  3. The method according to claim 1, characterized in that the PP-2 is screened, the resulting rock mass with a particle size of more than +0.08 mm is subjected to grinding, with a particle size of less than -0.08 mm, the first processing step of PP-2 is carried out at a Knelson concentrator, mining the weight of PP-2 with a particle size of +0.06 mm is subjected to additional grinding, with a particle size of -0.06 mm, the second processing step of PP-2 is carried out at a Knelson concentrator, the ore mass of PP-2 with a particle size of more than + 0.04 mm is subjected to additional grinding, with a particle size of less than -0.04 mm subjected to the third operation processing of PP-2 at a Knelson concentrator, in which a heavy fraction and product are recovered for re-screening, after which the ore mass with a particle size of more than + 0.02 mm is subjected to additional grinding, and the ore mass of less than -0.02 mm is subjected to the fourth processing operation of PP-2 at the Knelson concentrator, the heavy fractions obtained at the Knelson concentrators are sent for further processing of platinum-palladium metals, and the tailings are sent to the intermediate product PP-3 for processing by a bacterial chemical tank m means.  4. The method according to claim 1, characterized in that to determine the contrast and x-ray concentration of ores, geological and technological mapping of the processed ores and dump products is carried out with the spatial variability of the optimal grain size of platinum-palladium metals being determined, while the studied ore deposit or old dead dumps are divided into individual small ore blocks and in each of them determine the optimal grain size of platinum-palladium metals.  5. The method according to claim 1, characterized in that the mining mass of the intermediate product PP-3 is directed to a bacterial-chemical vat leaching with a heated bacterial solution in the winter and autumn-spring periods, the circulation of hot water in water shirts that heat eight sections of the tub leaching, one tank for the deposition of platinum-palladium metals and a reservoir for spent solutions, is carried out using a tank for heating hot water and a pump. 6. The method according to claim 1, characterized in that the heating of the bacterial solution in the sections of the vats for leaching, clarification of the solution, the deposition of platinum-palladium metals and the reservoir for spent solutions in the winter and autumn-spring periods is carried out using double walls - water shirts of the vats for leaching , clarification of the platinum-palladium metal deposition solution and the spent solution tank with a distance between double walls of 3 - 7 cm, through which hot water is continuously pumped using a pump, heating portable batteries, in large frosts -20-35 ^o C, portable batteries are installed in the sections for leaching, clarification of the solution, and platinum-palladium metal precipitation for heating the bacterial solution, hot water is continuously pumped through the portable batteries and the bacterial solution is additionally heated in winter air temperatures below -20-35 ^o C. 7. The method according to p. 1, characterized in that the increase in sensitivity and selectivity of x-ray radiometric sorting and separation of sulfide copper-nickel ores is implemented by using as a criterion for the separation of ores the product of the analytical parameters of the elements - indicators Cu, Ni, Co, Sn, Pb, Bi , As, Sb, while the criterion for the separation of sulfide copper-nickel 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 — scattered radiation intensities of Plutonium-238 sources recorded in the energy range 13.6 - 16.8 KeV;
N _Nii — nickel CRI intensities recorded in the energy range 7.1–7.7 keV;
N _S2i is the intensity of the scattered radiation of Cadmium-109 sources, recorded in the energy range of 19.0 - 21.5 KeV;
N _Coi are the CRI intensities of cobalt recorded in the energy range of 6.7 - 7.1 KeV;
N _S3i are the intensities of the scattered radiation of Cadmium-109 sources, recorded in the energy range of 19.0 - 21.5 KeV;
N _Sni — tin HRI intensities recorded in the energy range of 25.0–25.4 keV;
N _S4i — 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 _S5i are the intensities of the scattered radiation of Cadmium-109 sources recorded in the energy range of 19.0 - 21.5 KeV;
N _Bii — bismuth CRI intensities recorded in the energy range of 10.5 - 10.9 KeV;
N _S6i are the intensities of the scattered radiation of Cadmium-109 sources recorded in the energy range of 19.0 - 21.5 KeV;
NAsi — arsenic HRI intensities recorded in the energy range of 9.5–11.5 keV;
N _S7i - the intensity of the scattered radiation of Cadmium-109 sources, recorded in the energy range of 19.0 - 21.5 KeV;
N _Sbii — antimony CRI intensities recorded in the energy range 26.1–26.5 keV;
N _S8i are the intensities of the scattered radiation of Americium-241 sources recorded in the energy range 48 - 59.0 KeV.  8. The method according to claim 1, characterized in that in the regions of the Far North, operations are introduced to control the volume and weighted average content of platinum-palladium metals of the ore mass of intermediate products PP-1, PP-2, PP-3 and enriched OP products to reduce volumes in winter intermediate products PP-1, PP-2, PP-3 and their increase in the autumn-winter periods.

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