RU2051748C1 - Combination method for processing of copper ores - Google Patents

Abstract

FIELD: mining industry. SUBSTANCE: method involves transportation of ores, their express analysis by radiometric methods, averaging of quality of ores, heaped bacterial-chemical leaching and intensification of vital activity of bacteria. The ore mass is sorted into three grades: a relatively lean copper ore containing 0.2-0.9% Cu (intermediate product) is directed for bacterial-chemical leaching only in summer while in winter the intermediate product is stored on a sorting ground; a concentrated product containing 0.9-2.5% Cu and over is directed to floatation after averaging of quality; and final tailings after averaging of ore quality are dumped. Information received by microcomputers from RKS detectors mounted on RKS plants and separators gives ground for determining volume and content of copper, automatic adjustment of rock volumes in the intermediate product, concentrated product and final tailings, automatic adjustment of limiting contents of grading mechanisms and separators. EFFECT: higher efficiency. 9 cl, 1 dwg, 2 tbl

Description

 The invention relates to a technology for the beneficiation and processing of conditioned and off-balance copper ores based on the use of radiometric sorting, separation and heap bacterial-chemical leaching of copper ores and can be used in the mining industry.

 A known method of radiometric sorting and piecewise separation of ores of non-ferrous and rare metals. To average the quality of ores in the process of radiometric sorting and separation of ores, a known method is used, based on controlling the boundary content of radiometric sorting and piecewise separation of ores, determining the content of the useful component in the enriched product and dump tailings of radiometric sorting and separation of ores using detectors of ore-controlling stations (RKS) ) and the return of portions of ore with a high content of the useful component in the tailings. The disadvantage of this method is the impossibility of sharing radiometric sorting and separation and heap bacterial-chemical leaching of copper ores, which makes it difficult to involve poor and off-balance copper ores in heap bacterial-chemical leaching. The bacterial-chemical method for leaching copper ores allows the processing of poor and off-balance copper ores with a cost of 3-5 times lower than the cost of processing copper ores in the traditional way. This fact urgently requires the elimination of the disadvantage of this method.

 The additional involvement in the processing of 15-85% of off-balance ores with the content of 0.2-0.8 or 0.1-0.6% of copper using heap bacterial-chemical leaching of copper will significantly (by 5-35%) increase the extraction of copper from mined rock mass due to previously unused off-balance ores. This increase in copper recovery will occur without significant investment.

 The aim of the invention is to increase the extraction of copper from the mined rock mass of poor ores and the involvement in the processing of unused off-balance copper ore by sharing heap bacterial-chemical leaching in the process of radiometric sorting and piecewise separation of copper ores for conditions of northern and middle latitudes, as well as the conditions of the Far North.

 The prospect of involving large reserves of off-balance copper ores (Udokan deposit) in the process of beneficiation and processing is one of the factors that require the prompt implementation of the proposed invention in the practice of work.

 This goal is achieved by applying the method of radiometric sorting of portions and piecewise separation using a change in the boundary content, followed by averaging the quality of the enriched products of conditioned and off-balance ores and the bacteriochemical method of leaching copper ores with the subsequent physical, chemical and biological intensification of the activity of bacteria.

 In the present invention and using radiometric sorting of piecewise separation, the ore mass of copper ores is divided into three grades: relatively poor copper ore (grade 0.2-0.8% or 0.1-0.6% Cu) with a yield of grade 45-50 % due to increased boundary contents (intermediate product); enriched product of radiometric sorting (content 0.8-2.5% or 0.6-2.5% Cu and more) with a yield of 40-45% due to increased boundary contents (enriched product) and tailings (content 0.05 -0.2 or 0.05-0.1% Cu) with a tail yield of 10-15% Radiometric sorting is carried out all year round. The enriched product of radiometric sorting, after averaging the quality of the ores, is sent to an enrichment plant (RP) for flotation followed by pyrometallurgical smelting of concentrates. The intermediate product of radiometric sorting is directed to bacterial-chemical leaching. To reduce capital costs for the construction of special buildings, heap bacterial-chemical leaching of the intermediate product is planned to be carried out only in the summer (seasonal method), and in winter time the intermediate product is stored at the sorting site for its processing by bacterial-chemical leaching only in the summer. If the copper content in the dump tailings of the separation sorting is lower than the copper content in the dump tailings of flotation concentration, then the tailings are sent to the dump, if higher, then the portions of the dump tailings are returned to the separator inlet, for sorting according to the prototype to reduce the loss of a commercial product.

 For the implementation of heap bacterial-chemical leaching for 5-6 months of summer time in the conditions of northern and middle latitudes, as well as the conditions of the Far North, a number of technical solutions are envisaged: accelerating the process of intensification of the activity of bacteria; an increase in the rate of supply of the bacterial solution into the perforated pipes, an increase in pressure when the solution is created by the feed pumps; reduction of intermediate product volume by radiometric sorting and separation.

 Since the cost of processing copper ores by bacterial-chemical leaching is 3-5 times lower than the cost of processing copper ores in the traditional way, it is economically feasible to increase the volume of the intermediate product to obtain a cheaper final product. However, in the conditions of northern or middle latitudes, and especially the conditions of the Far North, summer time is significantly reduced, which is most favorable for seasonal heap bacterial-chemical most favorable for seasonal heap bacterial-chemical leaching. The acceleration of the process of bacterial-chemical leaching due to the intensification of the activity of bacteria, an increase in the feed rate of the bacterial solution and an increase in pressure during the supply of the solution creates the conditions for increasing the volume of the intermediate product. Since the above factors are variable, it is advisable to regulate the volume of the rock mass of the intermediate product, taking into account the increased efficiency of the economy and the real conditions of the northern and middle latitudes, as well as the conditions of the Far North, where copper ores are processed (Udokan deposit).

(3) где α_с.в. средневзвешенное содержание меди в суммарном товарном продукте;
Σ Р_тп, Σ Р_пп, Σ Р_оп, Σ Р_ох суммарный вес горной массы товарного продукта, промежуточного продукта, обогащенного продукта, отвальных хвостов;
Q_ох, Q_пп, Q_оп средневзвешенное содержание меди в отвальных хвостах промежуточном продукте и обогащенном продукте.The value of the regulated volume of the rock mass and the weighted average copper content of the intermediate product, taking into account the economy and the conditions of the northern and middle latitudes, as well as the conditions of the Far North, are determined by measuring the weighted average copper content and the amount of rock mass in the total product enriched in the product and dump tailings of radiometric sorting or separation from expressions:
Σ P _pp = Σ P _tp - Σ P _oh - Σ P _op. (one)
γ _pp = 100- γ _oh - γ _op (2)
Q _pp =

(3) where α _r.v. weighted average copper content in the total marketable product;
Σ P _tp , Σ P _pp , Σ P _op , Σ P _{oh the} total weight of the rock mass of the commercial product, intermediate product, enriched product, tailings;
Q _oh , Q _pp , Q _op weighted average copper content in the tailings of the intermediate product and enriched product.

(6)
В процессе регулирования объема горной массы промежуточного продукта выбирают оптимальный вариант для конкретных условий. В наиболее благоприятном варианте переработки медных руд обьем горной массы промежуточного продукта может быть увеличен до 65-75% от суммарного объема добытой горной массы на руднике. В наименее благоприятном варианте переработки медных руд объем горной массы промежуточного продукта может быть сокращен до 25-35% от суммарного объема добытой горной массы на руднике.The value of the volume of rock mass and the weighted average copper content of the enriched product, taking into account the economy and conditions of northern and middle latitudes, as well as the conditions of the Far North, is determined by measuring the weighted average content and amount of rock mass in the total product, intermediate product and tailings of radiometric sorting or separation from the expressions:
Σ P _op = Σ P _tp - Σ P _oh - Σ P _np (4)
γ _op = 100- γ _oh - γ _pp (5)
Q _op =

(6)
In the process of controlling the volume of the rock mass of the intermediate product, the best option for specific conditions is chosen. In the most favorable option for processing copper ores, the volume of the rock mass of the intermediate product can be increased to 65-75% of the total volume of mined rock mass in the mine. In the least favorable option for processing copper ores, the volume of rock mass of the intermediate product can be reduced to 25-35% of the total volume of mined rock mass at the mine.

Since the cost of processing copper ores of bacterial-chemical leaching is 3-5 times lower than the cost of processing copper ores by the traditional flotation method followed by pyrometallurgical smelting of copper ore concentrates, in all cases, if the natural conditions of northern and middle latitudes allow, it is necessary to strive to increase the volume of rock mass intermediate up to 65-75%
Operations to control the shares of rock mass and copper content are carried out using microcomputers installed at ore control stations (RKS) and separators. These micro-computers collect and process all the information received according to the prototype.

Q

(7) где Q_ко средневзвешенное содержание меди в обогащенном продукте для обогатительной фабрики (о.ф.).The magnitude of the change in the boundary content of radiometric sorting or piecewise separation is determined by the measured copper contents in portions of the enriched sorting and separation product and the amount of rock mass from the expression:
ΔQ _op = K

Q

(7) where Q is _the weighted average copper content of the enriched product for the enrichment plant (rf).

Q_ко в пределах ±2-5% (8)
По измеренным содержаниям меди в порциях отвальных хвостов сортировки или сепарации и количеству горной массы определяют величину граничного содержания из выражения
ΔQ_ох= K

Q

(9) где Q_хо средневзвешенное содержание меди отвальных хвостов для обогатительной фабрики (о.ф.).The increase in the boundary content of copper is carried out automatically until the moment when
Q

Q _to within ± 2-5% (8)
From the measured copper contents in the portions of the waste tailings of sorting or separation and the amount of rock mass, the boundary content value is determined from the expression
ΔQ _oh = K

Q

(9) where Q _ho weighted average copper content of tailings to concentrator (GF).

Q_хо (10)
Критерий выбора величины изменения граничного содержания определяют по выражению:

Q_ко (11)
при условии

Q

__→ 0
(12) где Q_ко оптимальное средневзвешенное содержание меди в обогатительном продукте обогатительной фабрики;
Q_хо оптимальное средневзвешенное содержание меди в отвальных хвостах обогатительной фабрики (флотация).The reduction of the boundary content of copper is carried out automatically until the moment when
Q

Q _ho (10)
The selection criterion for the change in the boundary content is determined by the expression:

Q _co (11)
given that

Q

__ → 0
(12) where Q is _the optimal weighted average copper content in the concentration product of the concentration plant;
Q _ho optimal weighted average copper content in the tailings of the processing plant (flotation).

 In order to reduce metal losses, the portions are recycled to the inlet of the sorter or separator if the copper content in the portions of the tailings exceeds the content of the tailings the recirculated portion of ore is re-sorted or separated with a reduced boundary content of the sorting device by Δ Q.

(13) где Q_ох, Q_пп, Q_оп средневзвешенные содержания меди в отвальных хвостах, промежуточном продукте и обогащенном продукте;
γ_ох, γ_пп, γ_оп средневзвешенный выход отвальных хвостов промежуточных и обогащенных продуктов.The value of the current weighted average copper content in the tailings of radiometric sorting or separation is determined by measuring the copper content in the total product, enriched product and intermediate product from the expression
Q _ooh =

(13) where Q _ooh , Q _pp , Q _op weighted average copper content in the tailings, the intermediate product and the enriched product;
γ _oh , γ _pp , γ _op weighted average yield of tailings of intermediate and enriched products.

A comparative analysis of the proposed technical solution with the prototype shows that the claimed method differs from the known prototype by the introduction of a number of new operations, namely:
In the proposed invention, by means of radiometric sorting and separation, the operations of dividing the rock mass of copper ores into three grades are introduced: an enriched product that is sent to flotation followed by pyrometallurgical smelting of concentrates, an intermediate product that is sent to heap bacterial-chemical leaching, and dump tailings that direct dump;
an additional operation was introduced to process the volume of the rock mass of the intermediate product using heap bacterial-chemical leaching of copper ores in northern and middle latitudes only in the summer (seasonal method), and in the winter time the intermediate product is accumulated at the sorting site for processing only in the summer ;
to implement heap bacterial-chemical leaching of copper ores of the intermediate product, additional operations have been introduced with the aim of accelerating the process of intensification of the activity of bacteria by accelerating the rate of supply of the bacterial solution into perforated pipes. The increase in pressure during the supply of the solution creating feed pumps, reducing the volume of the intermediate product by regulating the volume of the intermediate product by radiometric sorting or separation of copper ores;
additionally, the operation of regulating the volume and weighted average copper content of the rock mass of the intermediate product was introduced to reduce its volume in difficult conditions of northern and middle latitudes and increase its volume in more favorable conditions;
additionally, an operation was introduced to control the volume of rock mass and the weighted average copper content of the enriched product to change its volume in northern and middle latitudes and reduce its volume in more favorable conditions and increase the volume in adverse conditions;
additionally introduced the operation of changing the copper content in portions of the intermediate product and determining the volume of rock mass and the weighted average copper content of the intermediate product for various conditions;
using groups of detectors RKS and micro-computers installed at the input feed of the initial rock mass of sorting devices or separators and their inputs, the copper content of portions of the enriched product, intermediate product and dump tailings is additionally determined; the speed of feeding the bacterial solution into the perforated pipes, increasing the pressure during the supply of the solution creating by feeding pumps, reducing the volume of the intermediate product by regulating the volume of the intermediate product by radiometric sorting or separation of copper ores;
additionally, the operation of regulating the volume and weighted average copper content of the rock mass of the intermediate product was introduced to reduce its volume in difficult conditions of northern and middle latitudes and increase its volume in more favorable conditions;
additionally, an operation was introduced to control the volume of rock mass and the weighted average copper content of the enriched product to change its volume in northern and middle latitudes and reduce its volume in more favorable conditions and increase the volume in adverse conditions;
additionally introduced the operation of changing the copper content in portions of the intermediate product and determining the volume of rock mass and the weighted average copper content of the intermediate product for various conditions;
using groups of detectors RKS and micro-computers installed at the input feed of the initial rock mass of sorting devices or separators and their inputs, the copper content of portions of the enriched product, intermediate product and dump tailings is additionally determined;
additionally, the operation of determining the weighted average copper content in the tailings and recirculation of ore portions to the input of the sorter or separator was introduced, when the copper content in the waste tailings of the sorting and separation exceeds the content in the tailings of the beneficiation plant;
using the information obtained from the RKS detectors using microcomputers installed on the RKS installations or separators, operations are carried out to automatically control the rock mass of the enriched product, intermediate product and tailings, automatically regulate the boundary contents of sorting devices or separators and recirculate for an additional degree averaging the quality of ores at the lowest metal loss in the processes of sorting, separation and heap bacterial-chemical leaching Nia copper ores.

 The claimed technical solution is new and has an inventive step.

 Comparison of the claimed technical solution not only with the prototype, but also with other technical solutions in the field of radiometric beneficiation and heap bacterial-chemical leaching of copper ores did not allow to reveal the signs of the stated technical solution in them.

 The combined use of heap bacterial-chemical leaching in the process of radiometric sorting or separation of copper ores for conditions of northern and middle latitudes, as well as the conditions of the Far North and the development of combined technological systems, the additional operation of dividing the rock mass into three types of ores: intermediate product, enriched product and dump tailings and the implementation of heap bacterial-chemical leaching of copper ores in northern and middle latitudes only in the summer, is additional I the operation of controlling the volume of the rock mass of the intermediate product with the determination of the change in the volume of the rock mass of the intermediate product, and the additional operations of determining the copper content in the enriched product, the intermediate product and the tailings, as well as the recycling of portions of the tailings to reduce the loss of commercial product, are new signs for prototype, and for other well-known technical solutions, which allows us to conclude that the alleged invention meets the criterion of "substantial th difference. "

 The drawing shows a flow chart of a combined enrichment-bacterial method for processing copper ores for conditions of northern and middle latitudes.

 The initial copper ore with a particle size of less than 500 mm (-500) 1 is screened 2 in order to isolate a rock mass larger than 300 mm (+300), the ore +300 mm is crushed 3 and sent to large-size radiometric sorting of trolleys 4. Using an ore-controlling station (RKS) ) 5 by large-scale sorting, the rock mass is divided into five grades: rich ore 6, ordinary ore 7, poor ore 8, off-balance ore 9 and dump tailings 10. Rich copper ore with a grade of more than 2.5-3.5% without piecewise radiometric separation is sent to the quality averaging unit ud 11. Ordinary copper ore after screening 12 and crushing +150 mm 13, washing 14 and removing with drying and thickening the sludge 15 is sent to screening 16 with separation of particle size classes -200 + 80 17, particle size -80 + 50-18, coolness - 50 + 30-19 and piecewise radiometric separation of particle size class -200 + 80-20, particle size -80 + 50-21. size class -50 + 30-22 with separation of separation products into tailings 23 and concentrate 24. The tailings tailing tailings after averaging the quality of ores 25 are sent to sorting dump 26, and the concentrate to the averaging block of ore quality. Rich ore and lump separation concentrate undergo an operation to average the quality of ores, and the products are sent to the hopper of the total enriched product 27, from where they are sent to flotation 28 followed by pyrometallurgical smelting of concentrates 29. Poor and off-balance copper ores are sent to the heap bacterial-chemical leaching unit 30. After screening 31 and crushing 32 ore enters the heap 34.

The intermediate product (poor and off-balance ores) is sent to the heap bacterial-chemical leaching block. On flat areas with a special foundation 33 heaps 34 are poured, which are surrounded by a drainage ditch 35, from where the solution enters the settling pond 36 using pumps 37. The pond is divided into three parts, two of them settling tanks 38, one mixing chamber 39. The solution after leaching enters the head pond and, after settling, goes to cementation in the drum cementer 40. Copper extraction from the solution during cementation is 95% or more. The consumption of H ₂ SO ₄ is 5 kg / kg of recovered copper, and in the case of using theon bacteria in the leaching process, the acid consumption is reduced to 0.6-0.8 kg / kg of copper. The cement copper pulp after cementation is sent to a thickener 41, the discharge of which enters the tailings storage 42 and, after regeneration, is returned to the dump irrigation. The drying of cement copper is carried out at site 43, cement copper is collected in block 44. An evaporation site 45 is provided.

 Example. Let us consider the possibility of combined use of heap bacterial-chemical leaching in the process of radiometric sorting or separation of copper ores for conditions of northern latitudes using the example of the Udokan copper deposit.

 To assess the possibility of using a combined enrichment-bacterial method for processing copper ores of the Udokan deposit, it is necessary to evaluate the natural properties of copper ores.

 The generalized forecasted results of determining the contrast index for the Udokan field are given in Table. 1.

The average contrast ratio (P _max ) for pieces with a grain size of 200/30 mm is 1.24. The average contrast ratio for fine-graded sorting is 1.17, for sorting trolleys 1.14, for sorting dump trucks 1.10. The copper ores of the Udokan deposit should be attributed to the technological type of medium-contrast ores.

 The generalized results of determining the practical technological indicators of traditional radiometric ore preparation for the Udokan copper deposit are given in table. 2.

The practical yield of tailing tailings of the Udokan deposit for the studied varieties is 16-33%. The average practical yield of tailing tailings of the Udokan deposit is 26.1% for traditional fine-graded sorting 19.5% for the traditional sorting of dump trucks 10.0%
The natural properties of copper ores of the Udokan deposit are favorable for heap bacterial and chemical leaching of ores, since clay rocks in the ore bundle occupy only 3-5% of mudstones, quartz sandstones, siltstones, siltstone sandstones, sandy limestones, conglomerate breccias prevail in ore ore providing favorable factors for heap bacterial and chemical leaching of copper ores. The mineral composition of copper ores is characterized by exceptional constancy.

 Predictive calculations of technological indicators of radiometric beneficiation of a combined enrichment and bacterial method for conditions of northern and middle latitudes (enriched product) for the Udokan deposit are made for two options: option B-1, off-balance ores, contouring of ore bodies is carried out using an on-board grade of 0.3% copper; option B-2. ordinary ores, contouring of ore bodies is carried out according to the cutoff grade of 0.6% copper.

 The performed calculations are given in table. N 3.

From the data table. N 3 it follows that for off-balance ores (B-1) the yield of the enriched product at elevated boundary grades of sorting (0.4-0.5% copper) is 25-50%, the content in the enriched product is 1.80-2.88% copper, the enrichment coefficient is 1.80-2.88, the total yield of the intermediate product and tailings is 75-50% For ordinary copper ores (B-2) when contouring on the cut-off grade of 0.6% copper, the yield of enriched product is at higher boundary sorting contents (0.6-0.7% copper) is equal to 35-60%; the content in the enriched product is 2.43-3.65% copper; scheniya is 1,56-2,34, overall yield of the intermediate product and tailings is 40-65%
It can be concluded that the natural properties of copper ores of the Udokan deposit are favorable for the use of a combined enrichment-bacterial method for processing copper ores.

Consider the technology for processing copper ores of the deposit and adjusting the volume of rock mass of the intermediate product, which is sent to the heap of bacterial-chemical leaching of copper ores. The optimum copper content in the commodity ore entering the concentration plant of flotation concentration (OF) is equal to Q _ko = 2.65% of copper. The copper content of concentrator tailings Q _ho <15% copper, and the inclination of not less than 86-90% weighted average content of marketed products arrive at the separation α _m = 1.37, yield tailings _oh γ = 12% yield enriched product γ _op = 40% dilution rate 10%
Using the expression (1, 2), we calculate the yield of the intermediate product γ _pp .

γ _pp = 100-12-40 = 48%
Using expression (6), we calculate the copper content in the intermediate product Q _pp .

0,61
Для усреднения качества медных руд используют условие усреднения 2,39<Q_ко<2,92. Если содержание Q_ко выходит за пределы усреднения, т.е. величины 2,39 и 2,92% меди, то осуществляют регулировку граничного содержания по выражениям (7,8,9,10) таким образом, чтобы содержание меди Q_ко не выходило за пределы величин 2,39 и 2,92% меди и соблюдалось условие (3, 6). Используя выражение (13), рассчитываем текущее содержание меди в отвальных хвостах
Q_ох=

0,13
В рассматриваемом текущем моменте Q_ох=0,13% и оно меньше величины Q_ок= 0,15% меди. Если содержание Q_ох превышает величину 0,15% меди, то осуществляется регулировка граничного содержания согласно выражений (7, 8, 9, 10). Чтобы обеспечить необходимое ресурсосбережение, нужно чтобы изменение граничного содержания превышало значение Δ Q_ох на такую величину, чтобы выполнялось условие Q_охi<15% меди. Если это условие не выполняется, то порции рециркулируют на вход сортирующего устройства или сепаратора и повторно сепарируют при других граничных содержаниях.Q _pp =

0.61
To average the quality of copper ores, an averaging condition of 2.39 <Q _ko <2.92 is used. If the content of Q _ko goes beyond averaging, i.e. 2.39 and 2.92% of copper, the boundary content is adjusted according to the expressions (7.8, 9.10) so that the copper content Q _ko does not go beyond the limits of 2.39 and 2.92% of copper and condition (3, 6) was satisfied. Using expression (13), we calculate the current copper content in the tailings
Q _ooh =

0.13
In the current moment, Q _oh = 0.13% and it is less than the value of Q _ok = 0.15% of copper. If the content of Q _oxy exceeds the value of 0.15% of copper, then the boundary content is adjusted according to the expressions (7, 8, 9, 10). To ensure the necessary resource saving, it is necessary that the change in the boundary content exceeds the value Δ Q _oh by such a value that the condition Q _oi <15% of copper is satisfied. If this condition is not met, then the portions are recycled to the inlet of the sorting device or separator and re-separated at other boundary contents.

The amount of recirculation of the tailings portions depends on the contrast of the copper ores. For high-contrast and medium-contrast copper ores, there is always a large number of pieces in which Q _oxy <15% copper and the number of recirculations is not large. It was experimentally established that for copper ores with a contrast ratio (P _max ) of more than 1.2, the number of recirculations does not exceed 2-5% and for copper ores where the contrast index (P _max ) is 0.9-1.2, the number of copper recirculations ores is in the range of 3-12% of the number of measured portions of copper ores.

 The above example shows the principles of regulating the volume of rock mass and the copper content of the intermediate product, the enriched product and the tailings according to the expressions 2, 3, 5, 6, 7, 8, 9, 10, 11, 12, 13.

 The considered example (Fig. 1) clearly shows that when averaging the quality of the ores of the enriched product and dump tailings, two levels of regulation are used: the volume of the rock mass of the intermediate product, the enriched product and dump tailings, and the boundary contents of the sorting devices or separators of the enriched product and dump tailings. The implementation of two levels of regulation is carried out automatically by the proposed technical method on six micro-computers, which process the information of six groups of detectors of the RCS installations (Fig. 1).

 The implementation of the regulation of the volume of the rock mass and the copper content of the intermediate product, the enriched product and the tailings is also carried out automatically by the proposed method on four micro-computers that process the information of four groups of detectors of the RCS installations (Fig. 1).

 The positive effect of the proposed method is due to the fact that the cost of heap bacterial-chemical leaching of copper ores is 3-5 times lower than the cost of processing copper by the traditional flotation method, followed by pyrometallurgical smelting of concentrates. The greater the volume of the rock mass of the intermediate product in the northern latitudes is processed according to the proposed technological scheme (Fig. 1), the greater the economic effect. The positive effect of the proposed method is also due to the possibility of involving in the processing of reserves of off-balance ores. As you know, the reserves of off-balance ores in the deposits range from 15-120% of the reserves of conditioned ores. The largest volume of off-balance ores is observed in stockwork-like copper-porphyry, skarn and pyrite-polymetallic deposits. For copper-molybdenum ores, patents of Russia can be used.

 The Udokan copper deposit also has fairly large reserves of off-balance ores. Additional (higher than planned) involvement in the processing of off-balance ores allows to obtain large resource savings in the processing of non-renewable raw materials.

 Thus, the alleged invention is industrially applicable.

Claims (7)

 1. COMBINED METHOD FOR PROCESSING COPPER ORES, including transportation of ores, their express analysis by radiometric (nuclear-physical) methods of ore portions, averaging of ore quality, radiometric sorting and piecewise separation, characterized in that, in order to increase the extraction of copper from mined rock mass poor ores and involving in the processing of unused off-balance ores, using the radiometric sorting and separation, the ore mass is divided into three ore products - relatively poor (poor) copper ore with a grade of 0.2 - 0.8 or 0.2 - 0.6% Cu (intermediate), an enriched product with a content of 0.8 - 2.5 or 0.6 - 2.5% Cu and higher and tailings with a content of 0.05 - 0.2 or 0.05 - 0.1 Cu, the enriched product of radiometric sorting and separation after averaging the quality of copper ores throughout the year is sent to an enrichment plant for flotation processing followed by pyrometallurgical smelting of concentrates, an intermediate product of radiometric sorting and separation is directed to heap bacterial-chemical leaching, which for Northern and middle latitudes are planned to be carried out only in the summertime (seasonal method), at the same time they intensify the activity of bacteria and regulate the volume of the intermediate product, when averaging the quality of ores, the copper content and the mass of portions going to the separator are measured, as well as the copper content and the mass of the regulated enriched product, intermediate product and dump tailings for sorting and lump separation, while if the copper content in portions of dump tailings for sorting and separation is higher than If the total content of copper in the tailings of the processing plant is reached, then the portions of the tailings are returned to the feed input to the separator and the copper content in the tailings of the sorting and separation after the return of the batches is determined; the obtained information is used to control the processes.  2. The method according to p. 1, characterized in that the intermediate product of radiometric sorting and separation in the winter for the conditions of northern and middle latitudes is accumulated at the sorting site.  3. The method according to p. 1, characterized in that they provide for the acceleration of the process of intensification of the activity of bacteria, increase the feed rate of the bacterial solution into the perforated pipes during bacterial-chemical leaching of the rock mass of the intermediate product.  4. The method according to p. 1, characterized in that the volume of rock mass of the intermediate product is regulated by changing the boundary content of copper during radiometric sorting and separation. 5. The method according to p. 1, characterized in that the value of the regulated volume of the rock mass and the weighted average copper content of the intermediate product, taking into account the economy and conditions of northern or middle latitudes, is determined by measuring the copper content and the amount of rock mass in the total product and tailings from the expressions
γ _pp = 100 - γ _oh -γ _op ;

where α _St - weighted average copper content in the total marketable product;
Q _{about x} , Q _{n n} , Q _{o n} - weighted average copper content in the tailings, intermediate product and enriched product;
γ _oh , γ _pp , γ _op - weighted average yield of tailings, intermediate product and enriched product. 6. The method according to p. 1, characterized in that the value of the volume of rock mass and the average weight of copper content of the enriched product, taking into account the economy and conditions of the northern latitudes, is determined by measuring the copper content and volume of rock mass in the total product, intermediate product and tailings from the expressions
γ _op = 100-γ _oh -γ _pp ;

7. The method according to p. 1, characterized in that with the help of microcomputers installed on the RCS and separators in the conditions of northern or middle latitudes, operations are carried out to control the rock mass of the enriched product, intermediate product and tailings. 8. The method according to p. 1, characterized in that the magnitude of the change in the boundary content of sorting and piecewise separation is determined by the measured copper contents in portions of the enriched separation product and the amount of rock mass from the expression

and the measured copper contents in the portions of the tailings of the separation and the amount of rock mass from the expression

where ΔQ _op , ΔQ _oh - the value of the boundary contents of copper, determined by the enriched product and dump tailings of separation:
K is a constant scaling factor;
Q _{p o} - optimal weighted average copper content in the enriched product of the processing plant (flotation);
Q _{x o} - optimal weighted average copper content in the tailings of the processing plant (flotation),
the choice of the optimal value is determined by the criterion

given that

9. The method according to p. 1, characterized in that the value of the current weighted average copper content in the tailings is determined by measuring the copper content in the total product, enriched product and intermediate product from the expression

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