RU2722675C1 - Method of enriching aqueous product solution during winter season and automatic control system for implementation thereof - Google Patents

Abstract

FIELD: mining.SUBSTANCE: proposed group of inventions relates to mining, to geotechnological methods of extraction of solid minerals, in particular, by underground leaching (UL) method with subsequent enrichment of produced aqueous solution and its hydrometallurgical processing can be used at development of: deposits in heavily flooded and unstable sedimentary rocks, ores of oxidation zones of sulphide deposits, off-balance areas, deep-lying deposits with poor ore, dumps and tailing dumps. According to the method, supply of aqueous product solution is performed automatically proportionally to decrease of water table level. Water is removed from the pool automatically by accelerated freezing of ice in the form of spheres and their periodic extraction from the near-surface water layer of the pool with subsequent return of water after enrichment in the process of underground leaching by impregnating swamp peat deposits, overlapping the extraction section of the ore deposit during spring melting of ice. Collective concentrate output is performed automatically at achievement of specified level of collective concentrate in volume of pool fluid. Method is carried out using an automated control system comprising an outdoor pool on a day surface of the earth, filled with an aqueous solution, pipeline for water supply of productive solution, equipped with shutoff valves, ice retainer, device for extraction of ice from water surface of pool, pipeline for distribution of collective concentrate of useful components of ore for storage, equipped with shutoff valves. System further comprises a wind trap, a waterfree ball-shaped core of the ice sphere, axial soppler feed lines of the industrial product, equipped with shutoff and control valves, servo drive, basin mirror level sensor, industrial raw material tangential sipping pipelines, equipped with shutoff and control valves, servo drive, basin mirror level sensor, ice sphere immersion sensor, trawl mesh mechanism for extraction of ice sphere from pool, pipeline of collective concentrate delivery, equipped with shutoff-control valves, servo drive, collective concentrate level gauge.EFFECT: technical result is providing effective enrichment of aqueous product solution in continental climatic conditions of Siberian winter, as well as recycling commercial water in process of underground leaching.8 cl, 3 dwg

Description

The invention relates to the field of mining, to geotechnological methods for the extraction of solid minerals, in particular, by the method of underground leaching (PV) with subsequent enrichment of the resulting aqueous productive solution and its hydrometallurgical redistribution. From the standpoint of physical and chemical geotechnology, PV can be used in the development of: deposits in heavily flooded and unstable sedimentary rocks; oxidation zones of sulfide deposits; off-balance plots; deep-seated deposits with poor ore; dumps and tailings (Portsevsky A.K., Katkov G.A. Geotechnology (physical and chemical), - M .: MGOU, 2004. - P. 20).

The proposed technical solution is expedient for applying for the development of a deep-lying irrigated iron ore deposit in a swampy area in the conditions of an undeveloped transport and energy infrastructure and continental climate, which is, for example, part of the West Siberian iron ore basin.

The fundamental possibility of such an application is shown in such sources of information as Vogman D.A. Iron ore base and geotechnological methods of mining / Abstract. doc. 11th All-Union. conf. on geotechnological mining methods. - M., 1976. - S. 39-42; A.S. USSR SV 1218082. The method of underground leaching of iron ores / Auth .: V.P. Nebera. I.G. Abdulmanov, K.I. Museynov. - Publ. 03/15/1986; Vogman D.A., Ivanov S.V., Korobkov Yu.I. Underground leaching of iron from the bowels / Seminar No. 19 of Moscow State University for the Humanities “Prospects for the development of physico-chemical methods of mining” // http: science.msmu.ru.

As an analogue, the method of geotechnological development of an irrigated deposit of brown-iron ore ores of an oolitic structure according to patent RU2600229, which consists in the fact that the section of the deposit to be developed, is drilled with technological wells on a specific grid, the wells are prepared for mining, and then through the mouth of the injection wells into a mineral layer is injected with a leaching agent, after which a productive solution is selected from the delivery wells using the pressure of the aquifer, the leaching agent is injected and the productive solution is delivered using the potential energy accumulated in the gas volume, namely, in the container with compressed gas at the mouth of the injection well and in a vacuum tank at the mouth of the production well, while the concentrated leaching agent is injected into the mineral layer upstream of the flooding mineral stream The transmission of a leaching agent diluted to an effective concentration through a certain thickness of the mineral layer in lateral strike is carried out in a homogeneous form together with the flood stream in the direction of its flow and with its characteristic natural filtration rate, and the resulting productive solution is collected and dispensed onto the day surface downstream of the flooding reservoir using the pressure of a given aquifer, a grid of technological wells is formed by alternating parallel rows of injection and delivery wells drilled across the direction of flow of the flooding reservoir of the mineral flow.

The disadvantages of the analogue are the lack of enrichment of the aqueous productive solution at the production site, the need to have renewable reserves of potential energy accumulated in the gas volume at the production site and the difficulty of working in winter conditions.

An analogous method according to patent RU2594912 for the development of a deep-lying watered deposit of brown iron ore oolitic ores by underground leaching of useful ore components by drilling geotechnological wells of a mining section along a grid formed by alternating parallel rows of injection and delivery wells drilled cross-section of the geological flow of the flowing stream from the flowing flood wells for mining, injecting the leaching agent through injection wells into the mineral layer, dissolving the mineral components of the ore to form a productive solution, dispensing the resulting productive solution through the producing wells to the day surface, while preparing the injection wells for mining in the surface part of the borehole equipment is carried out by attaching to the wellhead of each well a tank with a leaching agent, which is equipped with a shut-off and control arm atura, including a valve valve, which runs the inlet of the liquid leaching agent through the well into the mineral layer, the issuing wells are prepared for mining in the ground part of the downhole equipment by attaching a tank with a leaching agent at the mouth of each well, which is equipped with shut-off and control valves, including a valve valve working to inlet a liquid leaching agent through a well into a mineral layer, the production wells are prepared for mining in the ground part of the downhole equipment by connecting an empty collection tank to the wellhead of each well, which is equipped with shut-off and control valves, including a valve working to release the productive solution from the mineral reservoir through the well into the collection tank, and to supply the liquid leaching agent to the mineral reservoir and dispense the productive solution to the surface The river uses the regular daily action of the tidal wave of the earth’s surface over the field by turning on the valve valve of the dispensing well during the earth’s tide and turning on the valve of the injection well in the period of the low tide.

The disadvantage of the analogue is the lack of enrichment of the aqueous productive solution directly at the production site.

The closest analogue to the prototype is the method according to application No. 2018139445, characterized in that the mining process is organized by circulating an aqueous working solution that purposefully and periodically changes its properties at different stages of geotechnology, namely, first the swamp water from surface peat deposits accumulates in the lower tank wellhead reservoir, then daily during low tide, it is fed from the lower reservoir through a vertical borehole of large diameter and horizontal boreholes of small diameter into a mineral layer, where, mixed with a stream flooding, it exerts a leaching effect on iron ore and turns into a productive solution , which daily, during the tide of the earth, is issued along horizontal and vertical trunks of small diameter to the upper capacity of the wellhead reservoir, where useful components are extracted from it, and water freed from metals is drained onto the non-freezing surface of peat In the vicinity of the wellhead, and passing through the entire thickness of peat deposits, it again becomes swamp water, which is re-accumulated in the lower capacity of the wellhead reservoir and enters the mining process.

In this case, the extraction of useful components from the productive solution is carried out in a priority order, which is determined regularly at the next stage of field development on the basis of the need for a specific useful component of iron ore, namely, first, the most valuable useful component in the current time period is extracted by hydrometallurgy, then, in order decrease in value, selectively recover the remaining useful components, if it turns out that the selective extraction of the remaining useful components by hydrometallurgical means is ineffective, then the productive solution, after the most valuable useful component is extracted, as an intermediate product, is sent to obtain a collective concentrate of useful components for subsequent selective extraction of useful components in other ways, while the concentration of the intermediate product and its storage is carried out close to the mouth of a universal production well.

According to this method, when enriching an aqueous productive solution (concentration of an intermediate product), it is proposed to use the technical proposals for patent RU 26000229 (paragraphs No. 20 and No. 21 of the claims according to application No. 2018139445). This improves the proposed technical solution, but does not eliminate the problem as a whole.

A feature of environmental geotechnology for the development of an iron ore deposit according to the prototype (application No. 2018139445) is the extensive nature of PV, characterized by a large water circulation at relatively low specific concentrations of useful components of iron ore in an aqueous productive solution. This necessitates ensuring the effective removal of large enough quantities of water from the productive solution in a fairly short time during all seasons of the year.

According to the authors, within a day it can be mined and delivered to the surface in the collection tank of the wellhead reservoir of each production well up to 40 cubic meters per day. m of aqueous productive solution. Of these, up to 30 cubic meters. m, as an intermediate product containing a collective concentrate of useful components of iron ore, can be fed into an outdoor pool - a sump near the mouth of a production well. The surface of the pool mirror, with the dimensions of the mining cell adopted in the prototype (100 mx 150 m), taking into account land allotment for the road, drilling site, warehouses, storage and others, can be no more than 1 thousand square meters. m. If we take the ratio of the volume of collective concentrate to the entire volume of industrial product as 1:10, then this means that with 1 square. m of the pool mirror, a layer of water 27 mm thick should be removed during the day. Under natural conditions, the rate of water removal is an order of magnitude lower (first millimeters), and in the technical proposal for the prototype it is several times lower (according to the authors, 5–8 mm / day).

The task is to propose a method of accelerated enrichment of an aqueous productive solution in the winter season.

The essence of the new technical solution, it is advisable to consider a specific example, typical for the possible application of the invention. The Bakcharsky iron ore deposit (BZHRM) in the Tomsk Region of the Siberian Federal District of the Russian Federation can be used as an object of application of technical innovation.

Let us provide a brief description of the characteristics of climatic conditions in the BZHRM zone, which are used in the proposed technical solution. The information was borrowed from the collective work of Tomsk scientists Danchenko A.M., Zadde G.O., Zemtsov A.A., Zemtsov V.A., Inisheva L.I., Lukutin B.V., Mezentsev A.V., Maslov S.G., Nazarov A.D., Obukhov S.G., Sevostyanov V.V., Sevostyanova L.M., Slutsky V.I. Cadastre of Opportunities / Ed. B.V. Lukutin. - Tomsk: NTL Publishing House, 2002 .-- 280 p.

The composition of the characteristics of climatic conditions affecting the intensity of the process of removing water from the surface of the pool - sump includes: radiation regime; atmospheric circulation; air temperature; wind regime and precipitation.

Within the BZHRM contour (covered area of 560 sq. Km), the following climatic conditions are realized during the winter season.

Radiation mode. The arrival of solar radiation is determined by the length of the day and the height of the sun. The average solar time of sunrise and sunset and the length of the day (h, min) on the 15th day and month: November - 7, 45/15, 43/7, 58; December - 8, 40/15, 10/6, 30; January - 8, 35/15, 43/7, 08; February - 7, 35/16, 53/9, 18; March - 6, 18/18, 00/11, 42. The height of the Sun (degrees) at true noon on the 15th day of the month: November - 13, 6; December - 8, 7; January - 10, 8; February - 18, 9; March - 29, 8. The arrival of solar radiation in winter is up to 0, 15 MWh / m ² .

Atmospheric circulation. The main air mass forming the climate is the continental Arctic cold and dry air. Asian anticyclones are also very stable and create severe frosts, lasting more than 15 consecutive days, which are often accompanied by significant wind speeds, which increases the severity of winter. Cyclones in winter are more frequent and more rarely expressed, changing the weather during the day, causing snow to fall on atmospheric fronts.

Air temperature. The average annual air temperature is 1.4 ° C, and the monthly average winter temperature (° C): in November - 11.2; for December - 18.9; for January - 20.5; for February - 18.4; for March - 10.7. The average maximum (daily) air temperature (° C) is: in November - 7.6; in December - 14.8; in January - 16.4; in February - 13.3; in March - 4.8. The average minimum (night) air temperature (° C) - is: in November - 15.2; in December - 23.7; in January - 25.1; in February - 23.8; in March - 16.4.

The dates of arrival of negative daily air temperatures above and below certain limits and the number of days with temperatures exceeding its limits: for the limit - 5 ° C - 1.04 / 28.10 / 209; for the limit - 10 ° C - 17.03 / 9.11 / 236; for the limit of 15 ° C - 2.03 / 22.11 / 264; for the limit - 20 ° C - 31.01 / 21.12 / 323.

Wind mode. In winter, up to 58% of the winds blowing from the south and south-west, there are much less frequent winds north and east (5-11%). Repeatability (%) of wind and calm directions in the central month of winter January: C - 3; SV - 8; AT 5; SE - 10; S - 29; SW - 28; S - 10; SZ - 7; calm - 21.

The average monthly wind speed (m / s) is: in November - 4.1; in December - 3.6; in January - 3.4; in February - 3.5; in March - 3.8.

The average number of days with strong winds (more than 15 m / s): in November - 1.4; in December - 1.6; in January - 0.9, in February - 0.9; in March - 2.4. The specific wind power in winter is 146 W / m ² .

Precipitation. On the territory of the BZHRM, an average of more than 500 mm of precipitation falls annually; in the winter, up to 25% of the average annual rainfall. The thickness of the snow cover varies from 60 to 150 cm. Freeze-up usually occurs in November, and ice drift in April.

Taking into account the above characteristic of climatic conditions in the BZHRM circuit, it should be noted that during the winter season (five months a year), a favorable situation is formed for organizing the process of enrichment of an aqueous productive solution by removing water by freezing ice. In fact, with such average winter indicators as air temperature around - 16 ° С; wind speed - 3.6m / s; the specific wind power is 146 W / m ² , ice formation in reservoirs is carried out in 2-3 days on the surface of the reservoir, an ice layer up to 10 cm thick is formed. The enrichment method proposed by the prototype by static freezing of an ice layer on the pool surface into a formwork containing ice has a natural with a freezing rate of ~ 3 cm / day and a significant drawback - the need for cutting / cutting of formwork with ice from ice rims to enable its removal from the pool.

In the proposed circumstances, the task of improving the prototype can be solved by using new technical solutions in the form of a method and a device that implements it, accelerating the course of the enrichment process in the winter conditions of the mining site.

1. A method of enrichment of an aqueous productive solution during the winter season, including collecting an aqueous productive solution in the wellhead of a production well of a production site of an underground leaching of useful ore components by a leaching agent based on swamp water from peat deposits blocking the ore deposit, supplying an aqueous productive solution through the pipeline after extraction , if necessary, of the most valuable useful ore component, to an open pool on the surface of the earth near the mouth of the production well, stratification by settling liquid in the pool to the water fraction at the pool mirror and the fraction of the collective concentrate of useful ore components at the bottom of the pool, removing water from the surface pool mirrors by freezing ice and then removing it from the pool, dispensing collective concentrate through the pipeline for storage, characterized in that the supply of the aqueous productive solution is automatically proportional To reduce the level of the pool mirror, the water is removed from the pool automatically by accelerated freezing of ice in the form of spheres and their periodic extraction from the near-surface water layer of the pool with the subsequent return of water after enrichment to the underground leaching process by impregnation of wetland peat deposits that overlap the mining section of the ore deposit, during spring ice melting, the issuance of collective concentrate is carried out automatically when the specified level of collective concentrate is reached in the volume of the pool liquid.

2. The method according to p. 1, characterized in that the accelerated freezing of ice in the form of a sphere is carried out by rotating the sphere around the center of symmetry.

3. The method according to p. 2, characterized in that the rotation of the sphere is created by the outflow in the atmosphere of nozzle jets of the supplied aqueous productive solution onto the spherical freezing surface.

4. The method according to p. 3, characterized in that the outflow of nozzle jets of the supplied aqueous productive solution is carried out tangentially in the aqueous surface of the circular pool.

5. The method according to p. 2, characterized in that accelerated freezing is carried out until the sphere is immersed in the surface layer of the pool to a depth corresponding to covering more than three quarters of the spherical surface with water.

6. The method according to p. 1, characterized in that the accelerated freezing of ice in the form of a sphere is carried out by directed blowing with atmospheric air of the surface of the freezing ice.

7. The method according to p. 1, characterized in that the periodic extraction of frozen ice in the form of spheres from the pool is carried out by trawling.

8. An automated control system for implementing the method according to claim 1, comprising an outdoor pool on the day surface of the earth filled with an aqueous productive solution, an aqueous productive solution supply pipe equipped with shutoff valves, an ice fixer, an ice extraction device from the pool’s water surface, a collective dispensing pipe concentrate of useful ore components for storage, equipped with shutoff valves, characterized in that it contains a scoop, a water-melting spherical core of the ice sphere, axial nozzle pipelines for supplying industrial products, equipped with shut-off and regulating valves, a servo drive, a mirror level sensor for the pool, tangential nozzle pipelines for supplying industrial products equipped with shut-off and control valves, servo-driver, pool mirror level sensor, ice sphere immersion sensor, trawl net mechanism for extracting the ice sphere from the pool, collective concentrate discharge pipeline equipped shut-off and control valves, servo-drive, collective concentrate level sensor.

The proposed method is included in the water circulation scheme (Fig. 1) of ecological geotechnology for the development of an iron ore deposit, carrying out the operations of enriching an aqueous productive solution and / or industrial product and utilizing water after enrichment, returning it to the underground leaching of useful components of iron ore. The new technical solution locally intensifies the natural process of ice formation in open water bodies and accelerates the freezing of ice from the settled water in the settling basin with the subsequent removal of ice outside the basin, proposed in the prototype method, due to more complete use of cold and wind energy resources available in the BZHRM zone during the winter season from mid-November to mid-March.

The set of operations that improve the prototype method is implemented as follows.

The supply of an aqueous solution and / or by-product through the pipeline to the settling pool is carried out automatically in volumes that compensate for the drop in the level of the pool mirror due to the removal of water in the form of frozen ice. Collective concentrate is piped out for storage automatically in volumes determined by the capacity of the concentration process (the amount of water fraction removed from the pool liquid volume).

Water is removed from the pool both by natural freezing of ice on a carrier (according to the prototype), but not by a static but by a dynamic method, and by artificially enhancing ice formation due to the wind flow directed to the ice formation site with increased specific power and due to additional cooling of the water with frozen side of the pool of a special form.

Acceleration of ice freezing is carried out by:

- blowing of the ice-forming area by wind with a specific power of up to N = 1.5 kW / m ² (with the usual parameters for winter in the BZHRM zone: N = 146 W / m ² , average wind speed Vf = 3.6 m / s; air density ρ = 1.34 kg / m ³ );

- cooling the water layer from below with soil frozen to -20 ° C;

- moving the freezing layer of ice into the zone of action of artificial water-cooling factors.

In FIG. 2 shows: 1 - the core of the ice roll; 2 - ice sphere; 3 - scoop; 4 - axial nozzle pipelines for the supply of industrial product; 5 - tangential nozzle pipelines for the supply of industrial product; 6 - mesh mechanism for extracting an ice sphere from water; 7 - an outdoor pool on the day surface of the earth, filled with industrial products from the wellhead production wells; 8 - pool mirror; 9 - pipeline for the issuance of collective concentrate for storage; 10 - collective concentrate level sensor.

The spherical core 1 serves to fix the layer of freezing ice 2 on a spherical surface and is made of durable water-floating material, for example, wood. A scoop 3 picks up a moving stream of frosty air, concentrates it and directs it to the ice sphere 2. Nozzles 4 provide rotation of the sphere 2 in the vertical plane, and nozzles 5 - in the horizontal plane, freezing ice over the entire surface of the sphere 2. Sensor for monitoring the immersion of the sphere 2 in water (not shown in the figure) controls the volume of ice frozen on the core 1, the level sensor 8 of the pool 7 (not indicated in the figure) controls the installed liquid level in the pool, the collective concentrate level sensor 10 monitors the achievement of the set maximum and minimum level values. Trawl 6 extracts frozen ice in the form of a sphere into a reservoir, from which spheres 2 are regularly removed and delivered to peat deposits for spring thawing and conversion into swamp water, on the basis of which a leaching agent for underground ore leaching is obtained.

The general scheme of an automatic control system implementing the method is illustrated in FIG. 3.

In FIG. 3 shows: 2 - an ice sphere; 3 - scoop; 4 - axial pipelines for the supply of industrial product; 5 - tangential pipelines for industrial product supply; 6 - mesh mechanism for extracting an ice sphere from water; 7 - an outdoor pool on the day surface of the earth, filled with intermediate from the wellhead reservoir of a production well; 9 - pipeline for the issuance of collective concentrate for storage; 10 - collective concentrate level sensor; 11 - level sensor of the pool mirror; 12 - servo drive; 13 - shut-off and control valves.

The system’s work is organized simultaneously through three automatic channels: a product supply channel from the wellhead of the production well; collective concentrate storage channel; water return channel after enrichment in the process of underground leaching of ore.

The feed channel operates as follows. When lowering the level of the mirror 8 in the pool 7, the sensor 11 generates a control signal for the servo drive 12 to actuate the shut-off and control valves 13, which opens the lock on the axial nozzle 4 and tangential 5 pipelines, which, rotating the ice sphere 2, produce controlled tempering of the product in pool 7. When the level of the mirror 8 rises to the set position, the sensor 11 generates a signal for the servo drive 12 to reduce the flow of industrial product or shutoff valves 13.

The delivery channel operates as follows. When the sensor reaches the level of collective concentrate 10 of the upper (maximum) set level, a control signal is generated for the servo drive 12 to unlock the shut-off and control valves 13 and the production of controlled delivery of collective concentrate through the pipeline 9 for storage. After the sensor 10 reaches the lower (minimum) set level, a control signal is generated for the servo drive 12 to lock the shut-off and control valves 13 and stop the delivery of collective concentrate through the pipeline 9.

The return channel operates as follows. Under freezing conditions, in the surface layer in the pool 7, the water in the area of blowing of the scoop 3 is frozen by rotating the ice sphere 2. The rotation of the sphere 2 is ensured by the pressure of the flow of moving frosty air concentrated by the scoop 3 and the pressure of the flows concentrated by nozzles 4 and 5 supplied to the pool 7 industrial product. Upon reaching the set volume of ice frozen in the form of a sphere 2, the sensor for monitoring the immersion of the sphere 2 in water generates a control signal for the trawling actuator 6 to extract the sphere 2 from the pool 7. Then, the ice spheres 2 are transported to drained landfills created on the ore deposit on the overlying deposits of the swamp peat, where during the spring thaw, melt water, having passed the deposits of peat, is converted into swamp water - the basis of the leaching agent used in underground leaching of ore.

It should be noted the role of the geometric factor in the growth of the freezing surface on the ice fixer of a flat, cylindrical or spherical shape. The experiment confirmed the advantage of curved surfaces over a flat one in terms of the specific productivity of freezing ice from 1 sq. Km. m of the water surface of the settling basin, ceteris paribus. It was found that the specific productivity of freezing the plate, cylinder and sphere are related to each other as 1: 3: 4.

In addition, the use of dynamic freezing of ice on a rotating sphere does not allow the latter to freeze to the edges of the ice and, therefore, there is no need to cut the sphere out of the edges of the ice when it is removed from the settling basin.

The technical result from the use of the invention is to provide effective enrichment of the aqueous productive solution in the continental climatic conditions of the Siberian winter while creating a synthetic environmental and economic effect due to spring recycling of process water into the underground leaching process in the geotechnology of developing the iron ore deposit.

Claims (8)

1. A method of enrichment of an aqueous productive solution during the winter season, including collecting an aqueous productive solution in the wellhead of a production well of a production site of an underground leaching of useful ore components by a leaching agent based on swamp water from peat deposits blocking the ore deposit, supplying an aqueous productive solution through the pipeline after extraction , if necessary, of the most valuable useful ore component, to an open pool on the surface of the earth near the mouth of the production well, stratification by settling liquid in the pool to the water fraction at the pool mirror and the fraction of the collective concentrate of useful ore components at the bottom of the pool, removing water from the surface pool mirrors by freezing ice and then removing it from the pool, dispensing collective concentrate through the pipeline for storage, characterized in that the supply of the aqueous productive solution is automatically proportional To reduce the level of the pool mirror, the water is removed from the pool automatically by accelerated freezing of ice in the form of spheres and their periodic extraction from the near-surface water layer of the pool with subsequent return of water after enrichment to the underground leaching process by impregnation of swamp peat deposits that overlap the mining section of the ore deposit at spring melting of ice, the issuance of collective concentrate is carried out automatically upon reaching a predetermined level of collective concentrate in the volume of pool fluid. 2. The method according to p. 1, characterized in that the accelerated freezing of ice in the form of a sphere is carried out by rotating the sphere around the center of symmetry. 3. The method according to p. 2, characterized in that the rotation of the sphere is created by the outflow in the atmosphere of nozzle jets of the supplied aqueous productive solution onto the spherical freezing surface. 4. The method according to p. 3, characterized in that the outflow of nozzle jets of the supplied aqueous productive solution is carried out tangentially in the aqueous surface of the circular pool. 5. The method according to p. 2, characterized in that accelerated freezing is carried out until the sphere is immersed in the surface layer of the pool to a depth corresponding to covering more than three quarters of the spherical surface with water. 6. The method according to p. 1, characterized in that the accelerated freezing of ice in the form of a sphere is carried out by directed blowing with atmospheric air of the surface of the freezing ice. 7. The method according to p. 1, characterized in that the periodic extraction of frozen ice in the form of spheres from the pool is carried out by trawling. 8. An automated control system for implementing the method according to claim 1, comprising an outdoor pool on the day surface of the earth filled with an aqueous productive solution, an aqueous productive solution supply pipe equipped with shutoff valves, an ice fixer, an ice extraction device from the pool’s water surface, a collective dispensing pipe concentrate of useful ore components for storage, equipped with shutoff valves, characterized in that it contains a scoop, a water-melting spherical core of the ice sphere, axial nozzle pipelines for supplying industrial products, equipped with shut-off and regulating valves, a servo drive, a mirror level sensor for the pool, tangential nozzle pipelines for supplying industrial products equipped with shut-off and control valves, servo-driver, pool mirror level sensor, ice sphere immersion sensor, trawl net mechanism for extracting the ice sphere from the pool, collective concentrate discharge pipeline equipped shut-off and control valves, servo-drive, collective concentrate level sensor.

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