RU96110971A - COMBINED METHOD FOR PROCESSING SILVER-CONTAINING ORE - Google Patents

Claims (11)

1. A combined method for processing silver-containing ores, including transportation of ores, their express analysis by nuclear-physical (radiometric) methods of ore portions, averaging of ore quality, nuclear-physical sorting and piecewise separation of complex silver-lead ores, silver-arsenide ores, silver-arsenide tin ores, silver-copper-nickel ores, silver-copper-molybdenum ores, characterized in that, in order to increase the extraction of silver from poor and off-balance ores, old dumps of off-balance ores, tailings By means of nuclear physical sorting and separation, the ore and silver slag dumps of the pyrometallurgical processing of complex silver-containing ores are divided into five ore products - enriched OP products with a silver content of more than 120 - 180 g / t, which are sent to the metallurgical processing of ores in the traditional way , intermediate products PP-1 with a silver content of more than 40 - 80 g / t, intermediate products PP-2 with a silver content of 5 - 20 to 40 - 80 g / t, intermediate products PP-3 with a silver content of m 5 to 20 g / t and OX tailings with silver content less than 0.5 - 2 g / t, which are sent to the dump, intermediate products PP-1, PP-2, PP-3 are sent to heap bacterial-chemical leaching at with the help of thionic bacteria T. ferrooxidans only in the summer, for the processing of refractory complex refractory complex silver-containing ores, the operations of two-stage bacterial-chemical leaching of silver-containing ores are introduced with regrinding of the collective concentrate after each leaching stage, when refractory ores are extracted silver is produced from silver-lead and silver-tin ores for the intermediate product PP-3 using sulfur dioxide, the silver content in the products of sorting and piecewise separation is determined by using linear correlations of silver with associated indicator elements Pb, Zn, Cu, Ni To increase the sensitivity and selectivity of silver-lead ores, Co, Bi, Sb, Sn, Mo use the products of the analytical parameters of indicator elements of lead, zinc, copper, su To increase the sensitivity and selectivity of silver-tin ores, we use the products of analytical parameters of indicator elements of tin, lead, zinc, for silver-copper-nickel ores use the products of analytical parameters of indicator elements of nickel, copper and cobalt, for silver -copoly-molybdenum ores use the products of the analytical parameters of the elements of the indicators of molybdenum, copper, lead and zinc, realize the intensification of the activity of bacteria and regulate the volumes of intermediate ny products PP-1, PP-2 and PP-3 using micro-computers.  2. The method according to p. 1, characterized in that the intermediate products PP-1, PP-2, PP-3 of nuclear-physical sorting and separation of complex silver-containing ores in the winter for the conditions of northern and middle latitudes are accumulated at the sorting site and processed bacterially -chemical method only in the summer.  3. The method according to claim 1, characterized in that for the processing of refractory refractory complex silver-containing ores, two-stage bacterial-chemical leaching of silver-containing ores of intermediate products PP-1 and PP-2 is introduced with regrinding of the collective concentrate after each leaching stage for the intermediate product PP -1 carry out single-stage bacterial-chemical leaching, for the intermediate product PP-2 carry out two-stage bacterial-chemical leaching with pre-grinding Collective concentrate after the first and after the second leaching stage. 4. The method according to p. 1, characterized in that in the processing of refractory and difficult-to-concentrate ores, the extraction of silver from silver-lead and silver-tin ores for the intermediate product PP-3 involves the operation of using sulfur dioxide, while processing with SO ₂ gas the pulps are realized in steel pressurized reactor, the off-gases are washed in scrubber water and then with caustic solution to remove the HCN and SO _2, after the pretreatment, the pulp is neutralized, the neutralized tails cyanating, whereupon the pulp is fed to vats for development of the "carbon-in-pulp", after thickening the pulp is sent to tailings and the solution, after osvetvlenie and reinforcements fed into circulation. 5. The method according to p. 1, characterized in that the increase in the sensitivity and selectivity of nuclear-physical separation and sorting of silver-lead ores is implemented by using as a criterion for the separation of ores the product of the analytical parameters of the indicator elements of lead, zinc, copper, antimony, tin and bismuth, while the separation criterion ξ of silver-lead ores is determined by the expression

where Npb _i are the intensities of the characteristic x-ray radiation (HXR) of lead recorded by each relay relay separator detector in the energy range of 11.5 - 13.0 KeV;
N _Si1 — scattered radiation intensities of Cadmium-109 sources recorded in the energy range of 19.0–21.5 keV;
NZn _i are the CRI intensities of zinc, recorded in the energy range of 8.4 - 8.8 KeV;
N _S2i are the intensities of the scattered radiation of Cadmium-109 sources recorded in the energy range of 19.0 - 21.5 KeV;
NCu _i are the CRI intensities of copper recorded in the energy range of 7.8 - 8.2 KeV;
N _S3i are the intensities of the scattered radiation of Plutonium-238 sources recorded in the energy range of 13.6 - 16.8 KeV;
N _S1bi — antimony CRI intensities recorded in the energy range of 26.1 - 26.5 KeV;
N _S4i — scattered radiation intensities of Americium-241 sources recorded in the energy range 48.0–59.0 KeV;
N _Sni — tin HRI intensities recorded in the energy range of 25.0–25.4 keV;
N _S5i — 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 _S6i 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 nuclear-physical detectors of the relay separator. 6. The method according to claim 1, characterized in that the sensitivity and selectivity of the nuclear physical sorting and separation of silver-arsenide ores are increased by using the product of the analytical parameters of the indicator elements nickel, cobalt and bismuth as a separation criterion, while the separation criterion ξ of silver-arsenide ores is determined by the expression

where N _Nii are the intensities of the characteristic X-ray radiation (XRD) of nickel recorded by each detector of the relay separator in the energy range of 7.1 - 7.7 KeV;
N _S1i are the intensities 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 _S2i 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 _S3i are the intensities of the scattered radiation of Cadmium-109 sources in the energy range of 19.0 - 21.5 KeV;
n is the number of nuclear-physical detectors of the relay separator. 7. The method according to claim 1, characterized in that the sensitivity and selectivity of the nuclear physical sorting and separation of silver-tin ores are realized by using as a criterion for the separation of ores the product of the analytical parameters of the indicator elements of tin, silver and zinc, while the separation criterion ξ of silver-tin ores is determined by the expression

where N _Sni are the HRI intensities of tin recorded in the energy range of 25.0 - 25.4 KeV;
N _S1i — scattered radiation intensities of America-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 _S2i 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 _S3i 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 nuclear-physical detectors of the relay separator. 8. The method according to claim 1, characterized in that the increase in the sensitivity and selectivity of nuclear physical sorting and separation of silver-copper-nickel ores is realized by using as a criterion for the separation of ores the product of the analytical parameters of the indicator elements of nickel, copper and cobalt, while separation criterion ξ of silver-copper-nickel ores, determined by the expression

where N _Nii are the CRI intensities of nickel recorded in the energy range of 7.1 - 7.7 KeV;
N _S1i are the intensities of the scattered radiation of Cadmium-109 sources, recorded in the energy range of 19.0 - 21.5 KeV;
N _Cui — copper CRI intensities recorded in the energy range of 7.8–8.2 keV;
N _S2i are the intensities of the scattered radiation of Plutonium-238 sources recorded in the energy range of 13.6 - 16.8 KeV;
N _Coi are the CRI intensities of cobalt recorded in the energy range of 6.7 - 7.1 KeV;
N _S3i is the intensity of the scattered radiation of Cadmium-109 sources, recorded in the energy range of 19.0 - 21.5 KeV;
n is the number of nuclear-physical detectors of the relay separator. 9. The method according to claim 1, characterized in that increasing the sensitivity and selectivity of nuclear-physical sorting and separation of silver-copper-molybdenum ores is implemented by using as a criterion for the separation of ores the product of the analytical parameters of the indicator elements of molybdenum, copper, lead and zinc , while the separation criterion ξ of silver-copper-molybdenum ores is determined by the expression:

where N _Moi are the HRI intensities of molybdenum recorded in the energy range of 17.3 - 17.5 KeV;
N _S1i are the intensities of the scattered radiation of Cadmium-109 sources, recorded in the energy range of 19.0 - 21.5 KeV;
N _Cui — copper CRI intensities recorded in the energy range of 7.8–8.2 keV;
N _S2i are the intensities of the scattered radiation of Plutonium-238 sources recorded in the energy range of 13.6 - 16.8 KeV;
N _Pbt — lead CRI intensities recorded in the energy range of 11.5 - 13.0 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 _Zni are the CRI intensities of zinc, recorded in the energy range of 8.4 - 8.8 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 is the number of nuclear-physical detectors of the relay separator.  10. The method according to claim 1, characterized in that for the extension of the season of heap bacterial-chemical leaching of silver-containing ores of intermediate products PP-1, PP-2, PP-3 for conditions of northern and middle latitudes, provide a solution for the bed of ore why lay a system of polyvinyl chloride pipes, realize the acceleration of the rate of supply of the bacterial solution into the perforated pipes, and also implement the intensification of the activity of thionic bacteria. 11. The method according to claim 1, characterized in that the value of the controlled volume of the ore mass and the weighted average silver content of intermediate products are PP-1, PP-2, PP-3, enriched products of OP and tailings ОХ, taking into account the economy and conditions of the northern and middle latitudes, evaluated by determining the silver content and the amount of ore in the total marketable products, enriched products and tailings from the expressions:
for intermediate products PP-1 nuclear-physical sorting and separation
γ _pp-1 = 100-γ _ox -γ _op -γ _pp-2 -γ _pp-3 ;

for intermediate products PP-2 nuclear-physical sorting and separation
γ _pp-2 = 100-γ _ox -γ _op -γ _pp-1 -γ _pp-3 ;

for intermediate products PP-3 of nuclear physical sorting and separation
γ _pp-3 = 100-γ _ox -γ _op -γ _pp-1 -γ _pp-2 ;

for enrichment of products of nuclear-physical sorting and separation

for tailings (OX) of nuclear physical sorting and separation
γ _ox = 100-γ _OP -γ _{claims 1} -γ _{2 -γ-claims of claims 3;}

where α _{St. Ag} - the weighted average silver content in the total marketable product;
γ _ox , γ _op , γ _pp-1 , γ _pp-2 , γ _pp-3 — yield of tailings, enriched products and intermediate products PP-1, PP-2, PP-3 sorting and separation of silver-containing ores;
Q _OXAg , Q _OPAg , Q _PP-1Ag , Q _PP-2Ag , Q _PP-3Ag - weighted average silver content in dump tailings, enriched products and intermediate products PP-1, PP-2, PP-3 sorting and separation of silver-containing ores.