RU2504437C2 - Dressing module for combined processing of permafrost tailings from dressing of impregnation copper-nickel ores of norilsk deposits - Google Patents

Abstract

FIELD: process engineering.

SUBSTANCE: invention relates to mining and can be used for extraction of valuable components and products of their processing, particular, for extraction of copper, nickel and iron sulphides and noble metals from aged tailings of suspended tailing pit of in cryolite zone of Norilsk deposits. Dressing module comprises open-pit field, two or three dredges, beach pump station consisting of stationary and vibratory screens, sunk basin with overflow pocket communicated by gravity feed hydraulic transport with open-pit field. Besides, it comprises two pump, pressure five-jet pulp separators communicated with vibratory screens, sunk basins and pump communicated with batteries of desliming 250 mm-dia hydraulic cyclones with their sand outlets connected via sunken basins and controlled-delivery pumps with said pressure five-jet pulp separators and, further, with rotary separators. Tailings from the latter are communicate by gravity feed hydraulic transport via appropriate sunk basin and controlled-delivery pump with mechanical camber flotation machine consisting of 130 m³-chambers. Concentrate outlet is communicated with appropriate sunk basin and controlled-delivery pump and, further, with pneumomechanical camber flotation machine consisting of four first-cleaner 17 m³-chambers. Concentrate outlet is communicated with appropriate sunk basin and controlled-delivery pump and, further, with pneumomechanical camber flotation machine consisting of four second-cleaner 8 m³-chambers. Module includes one or two giant jets installed in open-pit field lane, distribution box to direct portion of warm desliming drains by gravity feed hydraulic transport to open-pit field to accelerate tailing thaw and wash-off at two or more point of the pit and further direction to pit lane, screens mounted at beach pump stations, said screens feature 12-16 mm square meshes. Main flotation chamber has three chambers. Desliming hydraulic cyclones feature two cones with 20-10 deg-taper angle. Beach pump station sunk basin overflow pocket is additionally communicated by gravity feed hydraulic transport with two or three points of open-pit working board to return excess pulp into lane and to accelerate tailing thaw and wash-off.

EFFECT: higher yield and quality of flotation, decreased losses of valuable elements.

1 dwg

Description

The invention relates to the mining industry and can be used to extract valuable elements from ores and products of their processing, in particular for the extraction of sulfides of copper, nickel, iron and precious metals (in mineral and dispersed forms), from the stagnant tailings of the preserved tailings located in the permafrost zone Norilsk industrial region.

A known beneficiation module for the processing of gold-bearing ores, in which, during the technological process, pulp conveyors, vibrating screen, sump pump, hydrocyclones, arc screen, centrifugal concentrators, tail lock (RF patent 2211731, class B03B 7/00 are installed) , 9/00, publ. 09/10/2003.)

A disadvantage of the known module is the large loss of fine and pulverized gold of flotation size and the lack of technical ability to stabilize the initial supply of centrifugal separators in terms of pulp volume and solid content.

Also, a module is known for the enrichment of tailings material, including a dredger, a fixed screen with a mesh hole size of 15 mm, a pulp splitter, vibrating screens with a mesh hole size of 1.5 mm, a two-jet pulp splitter, pumps, two hydrocyclone batteries, a pump, a five-jet pulp splitter, concentrators, nine-jet pulp splitter, pneumomechanical flotation machines. (Blagodatin Yu.V., Yatsenko A.A., Zakharov B.A., Chegodaev V.D., Alekseeva L.I. Involvement in the processing of new raw materials of non-ferrous and noble metals. Non-ferrous metals. 2003, No. 8- 9.p.28-29).

In the known method, the efficiency of the module depends on the stability of the pulp supply, which is determined by many factors, in particular, the continuous operation of the dredger, and when it is moved to the bottom according to the scheme with a rotary-rotary pile course (or by any other scheme), technological stops are required for reloading piles, moving anchors, etc. (Nurok GA Processes and technology of hydromechanization of open cast mining. M., Nedra. 1985, p. 181-186), scheduled repair and unforeseen stops due to the ingress of foreign objects into the cut-off device. For these reasons, the pulp volume and the solid content in it are reduced in the module’s power supply. The surface of the stationary screen is clogged with coarse rocky soil, which covers the surface of the tailings to prevent dust removal and wind erosion, which also leads to a decrease in the flow of pulp into the module process. Non-pressure sumps with a valve system for distributing pulp lead to an uneven distribution of pulp volume over screens, hydrocyclone batteries and centrifugal separators, and as a result, overflow of pulp on screens, loss of pulp pressure at the inlet of preliminary classification hydrocyclone batteries, loss of quantity and quality of centrifugal concentrate separators.

Under these conditions, the parallel feeding of nine pneumomechanical flotation machines, with a chamber volume of 16 m ³ , does not make it possible to stabilize the pulp level in the flotation machines with sufficient reliability, which leads to irreparable losses of non-ferrous and noble metals with dump flotation tailings.

From the above it follows that the disadvantages of this method are:

- the hardware design of the module does not allow to stabilize the initial power supply of technological operations in terms of solid content and pulp volume;

- lack of reserve dredgers for short-term preventive and long-term repair work;

- the impossibility of uniform distribution of pulp in the equipment for screening and centrifugal enrichment using pressureless sumps;

- significant fluctuations in the pulp level in the chambers of flotation machines lead to irreplaceable losses of valuable elements.

Closest to the claimed technical solution is a module with a technological cycle that includes the main enrichment operations inherent in enrichment plants of high productivity and which includes: a quarry field, two or three dredgers; an onshore pumping station, consisting of a stationary and vibration screen, a sump with an overflow pocket in communication with the quarry field, two pumps with adjustable capacity; five-jet pressure pulp dividers; vibrating screens; sumps and pumps connected with batteries of dehumidifying hydrocyclones; sands of hydrocyclone batteries through sumps and pumps are connected with pressure five-jet pulp dividers and further with centrifugal separators; the tails of centrifugal separators are communicated with a sump and a pump, and then with a mechanical flotation machine, consisting of five chambers of 130 m ³ each and fed in series; the concentrate of five chambers of a mechanical flotation machine is communicated with a sump and a pump with adjustable capacity and then communicated with a pneumomechanical flotation machine consisting of four chambers (first re-cleaning) of 17 m ³ each and fed in series; the concentrate of the four chambers of the pneumomechanical flotation machine is in communication with the sump and the pump and then communicated with the pneumomechanical flotation machine consisting of three chambers (second cleaning) of 8 m ³ each and fed in series; the tails of the second flare are self-reportedly communicated with the first chamber of the first flare, and the tails of the first flare are communicated through a sump and pump with the first chamber of 130 m ^{3 of the} flotation machine. The concentrate of centrifugal separators and the flotation concentrate of the second treatment are communicated through a sump mixer with a high-pressure pump (RF patent 2 376069, KL C 2. Publ. 20.12.2009) Prototype.

In the known method, the efficiency of the module depends on the uniformity of the pulp supply from the quarry field to the technological process, despite the fact that 2 or 3 dredgers work in the quarry field, the speed of tailings defrosting in the bottom of the dredgers is low and does not allow it to withstand the given productivity in terms of solid with partial return of pulp from the onshore pumping station to the quarry field for defrosting and erosion of tailings.

To decontaminate the pulp, before subsequent operations - centrifugal beneficiation and flotation, standard single-cone hydrocyclones with a diameter of 250 mm and a taper angle of 20 degrees are used (Reference for ore dressing. Preparatory processes. Edited by OS Bogdanov. M ..., "Nedra", 1982 p. 189), the use of such hydrocyclones leads to sharp fluctuations in pulp density in the sands of hydrocyclones, with a sharp change in the power density of hydrocyclones (Povarov A.I. Hydrocyclones in enrichment plants. M., "Nedra", 1978 p. 83).

Maintaining the optimal pulp level in the pump sumps, due to the return of part of the discharge of hydrocyclones, leads to the accumulation of sludge in the circulation circuits - sump - pumps - hydrocyclones, ultimately, the number of sludge in the sands of hydrocyclones increases, which leads to siltation and pressing of the ring grooves of centrifugal separators and as a result, the quality of the concentrate is reduced not only centrifugal enrichment, but also the concentrate of the main flotation.

This field is located in the permafrost zone. Non-ferrous metal sulfides (pyrrhotins - hexagonal and monoclinic, pentlandite, chalcopyrite), precious metal minerals and their intergrowths with sulfides in the tailings are treated with reagents during ore dressing and are without exogenous surface changes, (Dodin D.A., Isoitko V.M. et al. Technogenic deposits of platinum raw materials of the Norilsk region. Collection of scientific papers. Platinum of Russia. Moscow. Geoinfomark AOZT, 1994 p. 134, 137.), therefore, conditioning of pulp in the contact tank before the main flotation does not affect the technological Kie indicators.

Tailings after dedusting and secondary enrichment (centrifugal separators and flotation) contain a minimum amount of sludge and can be used to build an environmentally friendly dam of the existing tailing dump. Sludge contains smectite minerals, the particle size of which is less than 1 μm and which, when wetted, increase in volume by up to 10 times (Godovikov A.A. Mineralogy. M., Nedra. 1983, p. 390). A decrease in the number of smectites allows one to reduce the ductility and increase the angle of internal friction of the tailings by 10-15% and ultimately increase the strength of the alluvial massif (dam) by 15-20% (Lolaev AB, Butyugin VV Geoecological problems of intentional hydraulic engineering in permafrost zone. Moscow. Mineral resources. 2005 p. 170).

Part of the low-solids hydrocyclone discharges, in addition to warm water (coolant), can be sent to the quarry field for defrosting, washing out and transporting the tailings to the lane, where dredgers are installed.

In the vertical section of the tailing pond, the content of non-ferrous and noble metals is 3-4 times higher than the minimum values, which is due to the different content of metals in the ore mined during the period of tailing operation, storage technology, interlayer tails and horizons, ice lenses (Dodin D.A., Isoitoko VM Super-large technogenic deposits of platinum metals. Ore dressing. 2006, No. 6, p. 20, Fig. 2 p. 20). In this regard, it is technologically necessary to be able to regulate the amount of concentrate and the time of the main flotation in order to obtain feedings that are stable in terms of metal content.

From the above it follows that the disadvantages of this module are:

- the hardware design of the module does not allow to reliably stabilize the initial power supply of technological operations for solid content and pulp volume due to the low speed of defrosting of the tailings in the bottom of dredgers and their transport from the sides of the quarry field to the lane;

- the use of standard hydrocyclones with a taper angle of 20 ° leads to significant fluctuations in the sand of hydrocyclones in density in the feed of centrifugal separators and flotation;

- the return of part of the discharge of hydrocyclones in the sumps of the pumps to maintain the level of pulp, leads to the accumulation of sludge and disruption of the process;

- conditioning of the pulp in the contact tank before flotation does not give a technological effect, since non-ferrous metal sulfides, precious metal minerals are treated with reagents during ore flotation and their surface after many years of storage in the permafrost zone is not subject to exogenous changes;

- storage of the coarse-grained part of the tailings with the minimum smectite content in the southern part of the same tailing dump, and they must be used for the construction of an environmentally friendly dam of the existing tailing dump;

- the lack of a system of defrosting, erosion and transportation of tailings by warm plums of de-clamming hydrocyclones to the mine of the quarry field;

- the lack of operational ability to reduce or increase the time of the main flotation and the amount of concentrate from this operation, with a low or high metal content in the initial tailings, due to the number of active chambers of flotation machines of the main flotation, which are fed in series.

The task of the invention is to reduce the irreparable loss of valuable elements with flotation tailings, to reduce the amount of smectite minerals in dump tailings. The technical result is an increase in the productivity, output and quality of the concentrate due to further stabilization of the power supply to the equipment of the processing plant in terms of pulp volume and solid quantity. Increasing the strength of the alluvial array of the dam of the existing tailing dump.

The solution to this problem is achieved by the fact that the known enrichment module, including a career field, two or three dredgers; a coastal pumping station, consisting of a stationary and vibration screen, a sump with an overflow pocket in communication with the quarry field, two pumps with adjustable capacity by changing the number of revolutions of the electric motors; five-jet pressure pulp dividers; vibrating screens; sumps and pumps in communication with dehumidifying hydrocyclone batteries, the pressure at the inlet of hydrocyclones being kept optimal by changing the speed of the pump motors, and if the pulp level in the sumps is reduced, the level is maintained within the specified limits by returning part of the hydrocyclone drains; sands of hydrocyclone batteries through sumps and pumps with adjustable capacity are communicated with pressure five-jet pulp dividers, and further with centrifugal separators; the tails of the centrifugal separators are gravitationally connected with the contact tank, the contact tank is connected with a sump and a pump with adjustable capacity, and then with a chamber flotation machine made of five mechanical chambers of 130 m ³ each, fed in series and the concentrate output is connected to the sump and pump with adjustable capacity and further communicated with the contact tank and the pneumomechanical flotation machine, consisting of four chambers (first cleaning) of 17 m ³ each and included in the circuit in series; the concentrate of four chambers of the pneumomechanical flotation machine is connected with a sump and a pump with adjustable capacity and then communicated with a pneumomechanical flotation machine consisting of three chambers (second re-cleaning) of 8 m ³ each and included in the circuit in series; the tails of the second flare are communicated with the first chamber of the first flare, and the tails of the first flare are communicated through a sump and pump with the first chamber 130 m ^{3 of the} flotation machine. The centrifugal separator concentrate and the second flotation concentrate are communicated through a sump mixer with a high-pressure pump, which pumps the total module concentrate into the hydraulic transport system, according to the invention, one or two floating hydraulic monitors are installed in a mine lane; at a coastal pumping station with a vibrating screen with a screen installed on it, with square holes with a side of 12 to 16 mm, a sump, with an overflow pocket in communication with gravity hydraulic transport with a career field to accelerate defrosting, erosion of tailings at two or three points of the side quarry and their hydrotransport to the lane; set two-cone hydrocyclones with a diameter of 250 mm with a taper angle of 20 and 10 degrees to de-slurry the pulp and create a density of sand (at the same time thickening occurs) corresponding to the regime map for subsequent technological operations of centrifugal enrichment and flotation; increase or decrease the amount of concentrate by changing the time of the main flotation depending on the content of non-ferrous metals in the feed, by stopping the chambers or lowering the pulp level in the second or third chambers, or simultaneously in the second and third chambers; a part of the warm drains of de-slamming hydrocyclones through a junction box communicated by gravity hydrotransport with a quarry field to accelerate defrosting, erosion of tails at two or three points of the quarry side and their hydrotransport to the quarry lane; coarse-grained tails with a minimum content of smectite minerals, by gravity hydrotransport or by pumps are sent to tailing pipes for further gravity transportation to the existing tailing dump, where it is used as a building material for the construction of a dam with a stable structure.

The invention is illustrated by the drawing, which shows a diagram of the hardware design of the module for combined processing of permafrost tails from the enrichment of disseminated copper-nickel ores of the Norilsk deposits.

The module includes: pit field 1, pit side 2, lane 3 with two or three dredgers 4 and one or two floating hydraulic monitors 5, an onshore pumping station consisting of a fixed 6 vibrating 7 screens, sump 8 with overflow pocket 9 to return excess pulp volume in the quarry field and associated defrost, erosion and transport of tailings at two or three points from the working side of the quarry to the lane; pumps 10 with adjustable capacity, two five-jet pressure head pulp dividers 11, ten vibrating screens 12 grids with holes or slots from 1.5 to 1.7 mm, two sumps 13, four pumps 14 with adjustable performance and four batteries of dehumidifying two-cone hydrocyclones 15 (in each battery has 16 hydrocyclones with a diameter of 250 mm, of which 6 can be switched on or off automatically or remotely by the operator depending on the pulp level in the sump and the pulp pressure at the entrance to the hydrocyclones), two sumps 16 and two a pump 17 with adjustable capacity in the feed of centrifugal separators, two five-jet pressure head pulp dividers 18, ten centrifugal separators 19, sump 20, pump 21 with adjustable capacity in the main flotation supply, three chambers of the mechanical flotation machine 22 with a volume of 130 m ³ each in the main flotation operation , foam troughs 23 of a mechanical flotation machine, sump 24 with a pump 25 with adjustable output in the feed of four chambers of a pneumomechanical flotation machine 26 with a volume of 17 m3 each, for the first cleaning of concentrate is the primary flotation sump 27, a pump 28 with adjustable output nutritional three chambers rotor flotation 29, with the volume of each chamber 8 m ³ each for a second recleaning concentrate sump 30, a pump 31 with adjustable output for supplying tailings first recleaning the main flotation; sump 32 with a mixer and two pairs of high-pressure pumps 33 (one pair reserve) for hydraulic transport of general concentrate; sumpf - divider 34 for directing part of the discharge of hydrocyclones of gravity hydraulic transport to the quarry field for defrosting, erosion and transport of tails at two or three points from the working side of the quarry to the lane. The tailings of the flotation machine 22 are directed by gravity hydrotransport or pumped out by pumps 37 through a sump 36 into two tailings 35 of the operating enrichment plant.

The module for combined tailings processing works as follows.

The initial product of the module is the stagnant tailings of the mothballed tailings from the enrichment of disseminated copper - nickel ores of the Norilsk deposits located in the permafrost zone, in the form of pulp they are fed by hydrotransport by two or three dredgers 4 from lane 3 of the quarry field 1, after thawing and erosion of frozen tails by draining of hydrocyclones, turnover floating hydraulic monitors 5. The desired high productivity of the quarry is provided by feeding the working sides of the quarry 2: returning excess pulp to three working points its side quarry for defrosting, erosion and gravity hydrotransport of tailings pulp from sump 8 through overflow pocket 9 to lane 3; feeding part of the warm discharge of hydrocyclones for defrosting, erosion and gravity hydraulic transport of tailings pulp from the sump of divider 34 to the working board of open pit 2 at three or two points and then to lane 3; supply of warm circulating water to the working board of opencast mine 2 for defrosting, washing out and gravity hydraulic transport of tailings pulp to lane 3. In lane 3, settled coarse-grained tails are washed out by floating hydraulic monitors 5, which simultaneously feed slurry under the milling cutters of dredgers 4, prevent siltation of lane 3 and maintain a certain depth and size of lane 3, necessary for maneuvering dredgers. From the lane, by dredgers along pressure pulp pipelines, in excess of volume, the pulp with a solid content of 5-15% is sent to a fixed 6 and vibrating 7 screens with a size of square mesh openings with a side of 12 to 16 mm. Oversize product with a particle size of more than 12-16 mm (coarse rocky soil and metallurgical slag) is sent for construction purposes. The under-sieve product enters sump 8, which is located under screens and pumps 10 with adjustable capacity, in the amount specified by the operator by volume of the pulp, and fed into the technological process of the concentration plant. The excess amount of pulp volume, through the overflow pocket 9 of the sump 8, as mentioned above, by gravity hydrotransport enters the working side of the quarry 2 for washing out the tailings. Thus, stabilization of the pulp volume and its required amount for subsequent technological operations are achieved.

Further, the pulp with two pumps 10 is fed to two pressure five-jet pulp dividers 11 at the outlet pipes, which, for each screen 12, have slide valves in a wear-resistant design with remote pneumatic control to connect or exclude each screen 12 from the circuit. There are screens with screens 12 gap size from 1.5 to 1.7 mm. The under-sizing product of the screens 12 enters the sumps 13, where the pulp level is kept constant due to a change in the number of revolutions of the pump motors using ultrasonic level sensors. When the number of revolutions changes, the volume of pulp entering the batteries of two-cone hydrocyclones 15 decreases or increases, respectively, the pressure at the inlet to two-cone hydrocyclones 15 increases or decreases, therefore, to maintain the pressure at the inlet of hydrocyclones, the number of drains of hydrocyclones is automatically added or reduced in the optimal mode. Constant pressure at the inlet stabilizes the solid content in the sands of hydrocyclones, while fluctuations in the solid content in the sands do not go beyond the centrifugal enrichment routine (43% solid ± 2%). Thus, two-cone hydrocyclones simultaneously perform two technological operations - deslamination (size classification) with the partial removal of smectites and thickening. The thickened sands of hydrocyclones through sumps 16, in which a constant level is maintained using ultrasonic level sensors and changes in the number of revolutions of the electric motors of the pumps 17, are sent to two pressure five-jet pulp dividers 18, on the outlet pipes of which gate valves are installed, in a wear-resistant design with automatic control from industrial logic a controller designed to control the operation of all five centrifugal separators 19, powered from one five-jet pressure pulp 18. The centrifugal separator concentrate is sent to the sump 32 with a mixer, for further hydrotransport by pumps 33. The tails of the centrifugal separators by gravity hydrotransport are sent to the sump 20 of the pump 21. In the sump 20, a constant pulp level is maintained by changing the number of revolutions of the pump 21. Then the pulp, from stable volume and solid content is sent to a mechanical flotation machine 22, consisting of three chambers of 130 m ³ each and fed in series. The pulp level and the height of the foam layer in the first, second and third chambers of the flotation machine 22 are automatically maintained constant at the optimum level on the instructions of the operator, in order to obtain a given quality of the main flotation concentrate, using a float sensor installed in the first chamber and one float sensor on the second and third chambers. The large total volume of the first chamber of the flotation machine smooths out possible minor changes in the volume of pulp due to the arrival of the tailings of the flotation machine 26 into the first chamber. When the non-ferrous metal content in the feed is reduced, the quality of the main flotation concentrate also decreases, and in order to maintain the quality of the concentrate, it is necessary to reduce the flotation front is three times, for this purpose, on the second and third cameras of the flotation machine, the pulp level is set by the operator to a minimum level so that there is no removal of foam containing th a large amount of waste rock in the foam chute 23, the second and third chambers. In this case, the first flushing will receive the main flotation concentrate from the first chamber, from which, after flushing, a conditioned concentrate is obtained for the content of non-ferrous and noble metals. With an average content of non-ferrous metals in the initial feed, the foam product is removed from the first and second chambers of the main flotation flotation machine. On the third chamber, an air damper is blocked, through which air enters to aerate the pulp and create a foam layer. In this case, there is no foam from the third chamber for removing foam into the foam trough 23. The quality of the foam product from the first and second chambers of the flotation machine ensures the production of a conditioned concentrate for non-ferrous and noble metals after cleaning. With a high content of non-ferrous metals in the feed, the foam product is removed from all three chambers. The tailings of the flotation machine 22, deslimified and with a minimum amount of smectite minerals, are pumped by gravity hydrotransport or, if necessary, by pumps 37 through sump 36 to the tailings of the existing ore processing plant that processes ore raw materials and then to the existing tailing dump. The concentrate of the flotation machine 22 is sent to a sump 24, in which the pulp level is kept constant by means of an ultrasonic sensor by changing the number of revolutions of the electric motor of the pump 25, which directs the concentrate to the pneumomechanical flotation machine 26 (the first purification of the concentrate) consisting of four chambers of 17 m ³ and included in circuit sequentially. The pulp level in the chambers is kept constant at a given level, by means of float sensors installed one for every two chambers. The tailings of the flotation machine 26 are combined with the initial power supply of the flotation machine 22, through a sump 30, in which a constant level is maintained by means of an ultrasonic sensor by changing the number of revolutions of the pump motor 31. The flotation machine concentrate 26 (after the first cleaning), through a sump 27, in which the pulp level is also supported constant using an ultrasonic sensor due to changes in the number of revolutions of the electric motor of the pump 28, is sent to the pneumomechanical flotation machine 29, consisting of three chambers of 8 m ³ each and powered data sequentially. The pulp level is maintained constant in all three chambers at a given level using a single float sensor. After the second cleaning, the concentrate enters the sump mixer 32, where a constant level is maintained using an ultrasonic sensor, by adding circulating water and changing the number of revolutions of the pump motor 33. The centrifugal separator concentrate is also sent to the sump mixer 32, and the combined factory concentrate with two pumps 33, connected in series (another pair of pumps is in reserve), pumping selective concentrates obtained from ore raw materials into the hydrotransport system.

The inventive module underwent industrial testing in the processing of stale tailings located in the permafrost zone from the processing of disseminated copper-nickel ores of the Norilsk deposits, additional products and profit from its sale were obtained.

Claims (1)

An enrichment module for the combined processing of permafrost tailings from the enrichment of disseminated copper-nickel ores of the Norilsk deposits, including a quarry field, two or three dredgers, an onshore pumping station, consisting of a fixed and vibrating screen, a sump with an overflow pocket communicated with a gravity two-hydrotransmitter pump with adjustable performance by changing the number of revolutions of electric motors, five-jet pressure head pulp dividers communicated with vibration thumps, sumps and pumps in communication with batteries of dehumidifying hydrocyclones with a diameter of 250 mm, the sand outlets of which through sumps and pumps with adjustable capacity are communicated with additional pressure five-jet pulp dividers, and then with centrifugal separators, the tail outlets of which by gravity pump and hydraulic transport with adjustable capacity communicated with a mechanical chamber flotation machine, consisting of chambers of 130 m ³ each, fed in series, and output concentrate which communicates with the sump and the pump with adjustable capacity and further communicates with the rotor flotation consisting of four cameras first recleaning, of 17 m ³ each and included in the circuit in series, the output of the concentrate four chambers rotor flotation communicates with the sump and the pump with adjustable capacity and further communicated with a pneumomechanical flotation machine, consisting of three chambers of the second re-cleaning with a volume of 8 m ³ each and included in series in the circuit, the output of the tailings of the second by means of gravity hydrotransport is communicated with the first chamber of the first purification, and the output of the tailings of the first purification is communicated through a sump and a pump with the first chamber of the mechanical flotation machine of the main flotation, the output of the centrifugal separator concentrate and flotation concentrate of the second purification are communicated through a sump mixer with a high-pressure pump, characterized in that the module is equipped with one or two hydraulic monitors installed in the mine of the quarry field, a junction box to direct part of the warm sinks hydrocyclones by gravity transport to the quarry field to accelerate the defrosting and erosion of tailings at two or three points of the quarry side and the subsequent direction to the quarry lane, installed at the onshore pumping station of the screen, made with square mesh openings from 12 to 16 mm in size, a flotation machine for main flotation made with three chambers, dehumidifying hydrocyclones made two-cone with a taper angle of 20 and 10 °, the overflow pocket of the sump of the coastal pumping station is additionally communicated by means of self Nogo hydrotransport with two or three working points of the edge of the pit to return an excess amount of pulp in the lane, and to accelerate the defrost and erosion tails.

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