RU2594912C2 - Method for development of deep water-flooded deposit of oolitic waste of ironstone ores - Google Patents

Abstract

FIELD: mining.

SUBSTANCE: invention relates to mining, specifically to geotechnical method for extraction of solid mineral deposits by underground leaching. Method for development of deep water-flooded deposit waste of ironstone oolitic ores by means of underground leaching of useful components comprises drilling geotechnical wells of production section at mesh formed by alternating parallel rows of injection and extraction wells, drilled across flow direction of flooded formation of mineral pressure flow, preparation of geotechnical wells to production of minerals, pumping leaching agent through injection well into formation of minerals, dissolution of useful components of ore with formation of productive solution, output onto day surface of obtained product of solution through extraction wells. Preparation of injection wells to production of minerals in surface part of downhole equipment is performed by connection to head of each well vessel with leaching agent, which is equipped with shutoff and control valves, including gate valve operating on liquid inlet leaching agent through well into formation of minerals. Preparation of extraction wells to production of minerals in surface part of downhole equipment is performed by connection to head of each well empty collection vessel, which is equipped with shutoff and control valves, including gate valve, working on output of productive solution of mineral bed through well into a collecting tank. To feed liquid leaching agent into formation of minerals and output of productive solution to day surface, regular daily action of tidal wave of ground surface above deposit is used by switching valve of extraction well in period of earth tide and switching valve of injection well in period of low tide. For cases when value of pressure of flow, flooding formation of minerals, above level of day surface of earth, vessel with leaching agent of injection well is arranged so that bottom of vessel is above level of well spring of amplitude of tidal wave, and container for collection of productive solution of extraction well is arranged so that its upper part is below level of well spring by amplitude of tidal wave.

EFFECT: improving leaching efficiency and environmental friendliness of process of underground leaching.

5 cl, 7 dwg

Description

The invention relates to the field of mining, to geotechnological methods for the extraction of solid minerals, in particular, the method of underground leaching (PV). From the standpoint of physical and chemical geotechnology, PV can be used in the development of: deposits in heavily flooded and unstable sedimentary rocks; ores of 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).

PV methods were developed when organizing the processes of uranium, gold and copper mining (see, for example, Arens V.Zh. Physicochemical geotechnology. - M.: Publishing House of MGU, 2001. - 656 C .; Underground leaching of polyelement ores. / Under the editorship of NP Laverov. - M .: Publishing House of the AGN, 1998. - 446 p .; EA Tolstov Physical and Chemical Geotechnology of Uranium and Gold Deposits Development in the Kyzylkum District. - M: Publishing House of MGU, 1999 .-- 314 p.).

Iron ore has a lower market value than the cost of uranium-containing, gold-containing or copper-containing mineral raw materials. However, there are options for cost-effective iron production using the PV method and from such raw materials. Technological implementations of these options are presented, for example, in such information sources as D. Vogman 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 physical and chemical methods of mining” // http://science.msmu.ru.

The known analogous method according to SU 1218082 includes opening waterlogged iron ore deposits in the wells, supplying sulfur dioxide gas to the technological wells simultaneously with oxygenated water, forming sulfuric acid as a leaching reagent, collecting and transporting productive solutions whose acidity is maintained in the range of ph = 1.5 -2.5. The disadvantages of this technical solution is the need at the place of iron extraction to have three components to obtain a leaching reagent, the effectiveness and quality of mixing of which depend on temperature and pressure.

Other analogous methods are known for the development of an irrigated iron ore deposit by the PV method, for example, by AS No. 1320418, a.s. No. 1234598, application RU 2001122130. A feature of the method as. No. 1320418 is the use of an underground water source for the extraction of solid minerals under the main condition for the implementation of this method - the presence of a powerful aquifer above the mineral layer. A distinctive feature of the method as. No. 1234598 lies in the fact that within the contour of the ore body, the pressure of groundwater is controlled by supplying or withdrawing water from aquifers through auxiliary wells. The disadvantage of these two methods-analogues is a very complex and expensive technological implementation. The method of extraction of solid minerals by leaching according to the application RU 2001122130 consists in drilling a section of a field to be developed with technological wells according to a specific grid, preparing the wells for extraction of minerals, then leaching agent is pumped into the mineral layer through the mouths of the wells, after which the leaching agent is pumped wells are selected productive solutions.

The disadvantage of this method is the need for drilling and arrangement of wells, supplying a layer of mineral water from a lower or overlying pressure aquifer. Increased in this regard, capital and operating costs, for example, in the development of a watered deep-lying iron ore deposit, increase the cost of the resulting productive solutions.

As the closest analogue prototype, the method of geotechnological development of an irrigated deposit of brown iron ore ore of an oolitic structure according to the application RU 2015 can be selected, namely, that the section of the deposit to be developed is drilled with technological wells on a specific grid, the wells are prepared for mining, then through the mouth of the injection wells, a leaching agent is pumped into the mineral layer, after which they are selected from the delivery wells using and the aquifer productive solution, the injection of the leaching agent and the issuance of the productive solution is carried out by using the potential energy accumulated in the gas volume, namely in a container with compressed gas at the mouth of the injection well and in a vacuum tank at the mouth of the delivery well, while the concentrated leaching agent is injected into the mineral layer produce upstream flooding the mineral stream, passing diluted to an effective concentration The leaching agent is centered through a certain thickness of the mineral stratum in lateral strike in a homogeneous form together with the flooding stream in the direction of its flow and with its characteristic natural filtration rate, and the productive solution obtained is collected and dispensed to the day surface downstream of the flooding layer mineral flow using the pressure of a given aquifer, a grid of technological wells is formed by alternating parallels the linear rows of injection and production wells drilled across the direction of flow of the flooding mineral layer.

As a disadvantage of the prototype, it is necessary to note the need to have renewable reserves of potential energy accumulated in the gas volume at the production site.

The task is to simplify the geotechnological development of a deep-lying irrigated deposit of brown iron-ore oolitic ores and to reduce the cost of the resulting intermediate product as a feedstock for the hydrometallurgical production of iron from it.

The problem is solved by the proposed combination of essential features of the invention, given below.

1. A method of developing a deep-lying watered deposit of brown iron-ore oolitic ores by means of 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 across the flow direction of the flooding reservoir of a mineral production well flow to the fossilized pressure head minerals, leaching agent injection through injection sk sinking into the mineral layer, dissolving the mineral components of the ore with the formation of a productive solution, dispensing the obtained productive solution through the delivery wells to the day surface, characterized in that the preparation of injection wells for mining in the surface of the downhole equipment is carried out by attaching a tank to the mouth of each well with a leaching agent, which is equipped with shut-off and control valves, including a valve operating on the inlet of the liquid leach agent through the well into the mineral reservoir, the preparation of the issued wells for mineral extraction in the above-ground part of the downhole equipment is carried out by attaching to the wellhead of each well an empty collecting tank, which is equipped with shut-off and control valves, including a valve valve that works to discharge the productive solution from the reservoir minerals through the borehole into the collection tank, and for supplying a liquid leaching agent to the mineral layer and issuing a productive solution ra to the surface using regular daily action of the tidal wave on the earth's surface by incorporating a valve deposit issued valve hole between earth tide and stored pressure switching valve valve period in wells earth tide.

2. The method according to p. 1, characterized in that for the case when the pressure head of the stream encircling the mineral layer is higher than the level of the surface of the earth, the reservoir with the leaching agent of the injection well is placed so that the bottom of the reservoir is higher than the level of self-discharge by an amount tidal wave amplitudes.

3. The method according to p. 1, characterized in that for the case when the pressure head of the stream encircling the mineral layer is higher than the level of the daily surface of the earth, the reservoir for collecting the productive solution of the issued well is placed so that its upper part is below the level of self-flow by the magnitude of the amplitude of the pouring wave.

4. The method according to p. 1, characterized in that the preparation of geotechnological wells for mining in the underground part of the downhole equipment is carried out by perforating the casing in the interval of the thickness of the mineral layer and equipping the perforated sections of the casing with packers that provide selective overflow of working fluids - leaching agent and productive solution - in the bedrock, or in the bottom, or in the middle part of the mineral layer with the implementation of several options Mining of the mining site: from top to bottom, from bottom to top or horizontally in the direction of flow of the flooding layer of a mineral mineral pressure stream.

5. The method according to p. 1, characterized in that the leaching agent used is obtained directly from the field from material from rocks lying on a mineral layer in the surface layer of the earth's interior, for example peat or brown coal.

It is advisable to make a description of the method for the development of a deep-lying watered deposit of brown iron-ore oolitic ores by the example of a specific geological object planned for development. As such, the Bakcharsky manifestation of iron ores in the Tomsk Region, which is part of the West Siberian iron ore basin, can be considered (Fig. 1).

The Bakcharsky occurrence is an integral part of the Bakcharsky ore cluster located in the Bakcharsky administrative district 200 km west of the city of Tomsk. Deposit area 1200 km ^2. Manifestation was discovered in 1957. Forecasted resources of manifestation by various studies are estimated at 18.3 billion tons [West Siberian Iron Ore, 1964; Goryukhin et al., 2000] up to 28 billion tons in the categories P ₁ + P ₂ [Geology ..., 2000]. According to E.V. Chernyaeva [Chernyaev et al., 1997], the estimated resources are 28.6 billion tons in the category P ₁ with an average Fe content of 34.12% and in the category P ₂ - 23.6 billion tons.

The ore body of the Bakcharsky occurrence is composed of the Bakcharsky, Kolpashevsky and Narymsky horizons, reaching a total thickness of up to 50 m, which contain strong cemented ores and the so-called “ore bulk”. According to the Tomsk exploration expedition [Nikonov et al., 2006], the capacity of the “ore granularity” of the Bakcharsky horizon is 6.8 m, and that of Kolpashevsky is 8.5 m; the total thickness of loose brown-iron-oolite ore is 15.3 m; bulk ores are absent in the Narym horizon. These loose oolitic getithydrogetite ores are primarily suitable for the application of geotechnological methods such as downhole hydraulic mining (SRS) and PV.

Ministry of Natural Resources of Russia in the period 2004-2014 carried out exploration work at the Bakcharsky manifestation, including with the aim of identifying the possibility of using geotechnologies in its development [Teplyakov et al., 2005; Lunev et al., 2009; Lunev et al., 2001; Teplyakov et al., 2001].

Another geotechnological feature, in addition to the presence of “ore bulk”, is the water cut of the Bakcharsky manifestation. According to the complexity of the geological-hydrological and mining-geological conditions, the subsoil plot of occurrence belongs to the 2nd group of complexity (classification of reserves and predicted resources of drinking, technical and mineral groundwater).

The hydrogeological conditions of the Bakchar iron ore manifestation can be presented on the basis of materials from the regional assessment of fresh and low-mineralized groundwater resources in the southern part of the West Siberian artesian basin and the results of hydrogeological studies for organizing centralized water supply to settlements in the southern regions of the Tomsk Region.

A characteristic feature of the occurrence of iron ore development horizons and their watering is the coordinated fall of horizons from SW to CER and the direction of the ground flow along A _s = 18 °.

In the regional plan, the hydrogeological section is characterized by a two-story structure, combining two hydrodynamic zones: intensive and delayed water exchange. The maximum power of the active water exchange zone is controlled by the depth of cut of the hydrographic network. When the ore stratum occurs at depths close to 200 m, the area of development planned for primary mining falls within the lower part of active water exchange. The hydrogeological section is characterized by the presence of several powerful aquifers sustained in plan and in section, some of which are used to organize centralized water supply to settlements. Groundwater of these horizons is part of a single hydrodynamic system of the West Siberian artesian basin.

For the presented technical solution, the fourth aquifer, confined to the deposits of the Gankinsky suite (K ₂ gn), is of interest. It is formed by flooded sands and has a large hydrostatic pressure and, without separating water resistance, passes directly into the iron ore stratum, which has low filtration parameters. The waters of the Gankinsky suite are fresh.

According to the source “Hydrogeology of the USSR, vol. XVI, West Siberian Plain” [Bulygin et al., 1970], the waters of the ore mass have a pressure of 160-200 m. Piezometric levels are set at a depth of -6 m below the earth's surface to +4, 5 m above her. The flow rates of the wells are 9.5-4.8 l / s, the specific flow rates are 0.95-0.68 l / s * m. Filtering coefficients according to laboratory data 1.64 m / day, according to pumping data from wells 1.56 m / day.

Another characteristic feature of the geological object under consideration is its location in the inaccessible taiga-marshy area in the zone of the world's largest Vasyugan swamp, in the absence of a developed transport and energy infrastructure of a sparsely populated territory. From experience in the development of oil and gas fields in the Tomsk Region (60-90s), it is known that cargo delivery to the fields is possible from mid-November to February by winter roads, two months in the spring by flood and year-round by helicopters. This circumstance significantly increases the cost of field development, in fact, the construction of one kilometer of road, power lines, and pipelines cost at least one million US dollars (in prices of those years). Shipping costs by air is even more expensive.

Thus, the enormous reserves of Bakcharsky brown iron ore, up to a third of the volume of which is in a loose, weakly bound state, flooded with a pressure stream, and the need to minimize transport and energy costs initiates the use of autonomous air defense with the possibility of obtaining a marketable product directly at the mining section of the field.

In FIG. 1 shows the layout of deeply irrigated brown-iron oolitic ores in the territory of the Tomsk region, where it is indicated: 1 - the administrative border of the Tomsk region; 2 - West Siberian iron ore basin; 3 - Bakcharskoe deposit of goethohydrogetite brown-iron ore of oolitic structure. The directions of the flow of underground pressure head fresh water in the strata of minerals from the southwest to the northwest and the movement of the regular diurnal tidal wave of the earth's surface over the territory of the region from B to Z are indicated.

Earth, sea, atmospheric tides are caused by the forces of attraction of the Moon and the Sun in conjunction with centrifugal forces developing during the rotation of the Earth-Moon and Earth-Sun systems (Big Encyclopedic Dictionary, http://dic.academic.ru). The largest of these forces - the lunar - determines the ebb and flow of water during the day. The tidal wavelength reaches several hundred kilometers, the wave amplitude in the open ocean is about 1 meter. The vertical displacement of the earth's surface reaches 0.5 m at the equator (0.35-0.40 m at the latitude of Moscow). The change in gravity reaches a value of 0.25 * 10 ^-5 m / s ² (0.25 mg) at the equator. The maximum rise in water at high tides is called "full water", the minimum - "low water". Tides daily go around the Earth from east to west, as well as the apparent movement of the moon. Tidal activity on our planet has been sufficiently studied and widely represented in the scientific literature (see, for example, Cupronickel P. Earth tides / Transl. From English. - M .: MIR, 1968. - 482 p.).

It should be noted that the sublatitudinal dimensions of the West Siberian iron ore basin 2, in the direction of the tidal wave, are close to the length of the tidal wave. This fact gives rise to the assumption about the quasi-resonant effect of the tidal wave on the rock mass lying on the ore bed, by analogy with the theory of the interaction of de Broglie waves associated with any material objects of wave nature (Feynman R., Leighton R., Sands M. Feynmanovskie Lectures on Physics, Issues 3-4, 3rd ed., Moscow: Mir, 1976, pp. 221, 222, 412). An increase in the amplitude of the earth's tidal wave over the iron ore basin 2 will be facilitated by the uncoupling of the solidity of the rock strata by powerful aquifers with weakened cohesion of solid particles.

The action of the tidal wave of the earth’s surface over the iron ore basin - a rock mass of 150-250 m, lying on the ore bed - is similar to the action of a peristaltic pump, which increases the head and flow rate of self-flowing wells during high tide.

The Bakcharskoye field 3, which has an area of more than 500 square meters, is supposed to be initially developed. km can be divided into production areas drilled by geotechnological wells along a grid formed by alternating parallel ores of injection and delivery wells drilled across the direction of flow of the flooding layer of a mineral fossilized pressure stream. In FIG. 2 is a diagram of the drilling grid with the accepted notation: 4 - injection well; 5 - issued well; 6 - security issued well; 7 - mark the location of the drilling of a geotechnological well; D is the row spacing; d is the interwell interval. The production site is developed by sequential or parallel mining of row spacing D of interacting injection 4 and 5 output wells. The guard rows of wells 6 protect undeveloped earth bowels from the negative impact of the leaching agent injected into the wells 4 and the productive solution discharged from the wells 5 and their mixture. Parameters D and d are selected based on geological and hydrogeological conditions and geotechnological requirements. For the conditions of the Bakcharskoye field 3, the optimal values may be D = 10 m and d = 5 m.

A typical PV process is shown in FIG. 3, where it is indicated: 8 - the day surface of the earth; 9 - a layer of mineral; 10 - overlying rock formation (seam roof); 11 - underlying rocks (bottom of the reservoir); 12 - leaching agent; 13 - soluble mineral; 14 - productive solution; 15 - injection of the leaching agent 12 through the injection well 4 into the reservoir 9; 16 - the issuance of the productive solution 14 through the issuing well 5 from the mineral 9. The essence of the PV consists in transferring the solid phase of the mineral 9 into the liquid phase 13 by means of agent 12 and the delivery of the productive solution 14 to the day surface 8. The roof waterproof properties 10 are used. and soles 11.

As noted above, the minimum piezometric level of fresh water 17 was established for Bakcharskoye field 3, flooding the ore bed 9, at a depth of 6.0 m below the surface of the earth 8 (Fig. 4a) - H _min = -6.0 m, and the maximum - above the surface of the earth 8 by H _max = + 4.5 m (Fig. 4b). This range of dispersion of piezometric levels over field 3 (more than 500 sq. Km) is an order of magnitude greater than the range Δ of tidal changes in water levels 17, which affects the level of capital costs (earthwork) and / or operating costs (sediment operation) at arrangement of the mining section of tidal airspace. However, in a significant part of the field 3, the values of the piezometric levels are positive and this contributes to the use of regular tide 18 (H + Δ) and low tide 19 (H-Δ) in the PF, as indicated in FIG. 5a and FIG. 5 B.

For the case when the pressure head of the stream encroaching the mineral layer 9 is higher than the level of the day surface of the earth 8, the reservoir 20 with the leaching agent 12 is injected with the injection of the well 4 so that the bottom of the reservoir 20 is higher than the self-discharge level H by the value of the tidal wave amplitude + Δ and the valve valve 22, working on the inlet of the liquid leaching agent 12 through the injection well 4 into the mineral layer 9, 13, was at the level of H + Δ (Fig. 6). At the same time, the reservoir 21 for collecting the productive solution 14 is placed so that its upper part is lower than the level of self-discharge H by the amount of reflux -Δ, and the valve 23 working to release the productive solution from the mineral layer 9, 13 through the issued well 5 to the team capacity 21, was at the level of H-Δ (Fig. 6).

The interaction of geotechnological wells 4 and 5 in the PF process is carried out by means of the corresponding inclusion of valve 22 during the tide, and valve 23 during the tide. This leads to the entry of agent 12 into the ore formation 9, dissolution of the ore 13 and the issuance of the productive solution 14 in the collecting tank 21.

In the event that PFs are exposed to powerful layers of “ore granulation”, then ballast rocks (oolite seeds, sand, clay) will accumulate in the volume of the reservoir’s area, the volume of which can reach up to one third of the volume mined.

In such conditions, there is a need to take measures to ensure effective PV in all areas of the worked volume. For this purpose, the preparation of geotechnological wells 4 and 5 for the extraction of minerals 9, 13, 14 in the underground part of the downhole equipment in the interval of the thickness of the mineral layer 9 is carried out by three-level perforation of the casing pipes and the equipment of the perforated pipe sections with packers providing selective overflow of working fluids 12, 13, 14 in the bedside 10, or the bottom 11, or in the middle part of the mineral layer 9 (Fig. 7). This allows you to implement several options for mining the mining site: from top to bottom (Fig. 7a); from bottom to top (Fig. 7c) or horizontally in the direction of flow of the flooding mineral layer of the pressure stream (Fig. 7b). By varying the opening of the perforated windows in the casing of wells 4 and 5, it is possible to change the dissolution of oolites in the process of PV taking into account the interfering ballast material in subsequent cycles by deposition of the latter on the sole 11.

Since the proposed method of tidal PV is a significantly extensive, environmentally friendly method of developing an iron ore deposit in its relatively large areas, the requirements for a leaching agent are assumed to be significant. Given the inaccessibility and infrastructural limitations in the development of the Bakcharskoye field, it is advisable to obtain a leaching agent directly from the field material from rocks lying on a mineral layer in the surface layer of the earth's interior, such as peat or brown coal.

It is likely that the first use of peat / coal reagents for dissolving and extracting iron from bog, lake, sod, limonite ores to produce powder crits and its pyrometallurgical processing or forging can be attributed to the Early Iron Age (see, for example, Grakov B.V. The Early Iron Age. - M., 1972; Anteyn A.K. Damascus steel in the countries of the Baltic Sea basin. - Riga, 1973). In the middle of the last century interest in the problem was supported in some works, for example, Kholodny N.G. Iron bacteria. - M., 1953 or Kovalev V.A., Generalova V.A. On the interaction of humic and fulvic acids of peat soils with iron. - Soil science. - 1967, No. 9. Currently, specialists in the field of water supply also continue to pay attention to the use of swamp water and well-decomposed peat (Teplyakov I.M. et al., 2001; Teplyakov I.M. et al., 2005).

From peat / brown coal mined by open-pit mining or through borehole hydraulic extraction, it is quite simple, directly in the field, to obtain water-soluble humic acids (for example, according to technical solution RU 2014119286) or, in the case of pyrolysis of peat raw materials, tar waters that can be used in as agents dissolving brown iron oolites. Since deposits of peat with a thickness of 2-19 m and brown coal with a thickness of 1.5-2 m almost completely cover the entire area of the Bakcharskoye field, from the reserves, along with the swampy waters of the Bakcharsky swamp and the world's largest Vasyugan swamp, it is enough for economic use in the Bakcharsky swamp ore.

The technical result achieved by using the method of developing a deep-lying oolitic ore deposit is to organize a more economical and more environmentally friendly PV process to produce valuable hydrometallurgical raw materials for the production of a scarce high-tech product - pure iron powder.

Claims (5)

1. A method of developing a deep-lying watered deposit of brown iron-ore oolitic ores by means of 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 across the flow direction of the flooding reservoir of a mineral production well flow to the fossilized pressure head minerals, leaching agent injection through injection sk sinking into the mineral layer, dissolving the mineral components of the ore with the formation of a productive solution, dispensing the obtained productive solution through the delivery wells to the day surface, characterized in that the preparation of injection wells for mining in the surface of the downhole equipment is carried out by attaching a tank to the mouth of each well with a leaching agent, which is equipped with shut-off and control valves, including a valve operating on the inlet of the liquid leach agent through the borehole into the mineral reservoir, the preparation of producing wells for mining in the ground part of the borehole equipment is carried out by attaching to the wellhead of each well an empty collecting tank, which is equipped with shut-off and control valves, including a valve valve that works to release the productive solution from the reservoir minerals through the borehole into the collection tank, and for supplying a liquid leaching agent to the mineral layer and issuing a productive solution ra to the surface using regular daily action of the tidal wave on the earth's surface deposit by incorporating a valve of the valve during dispensing wells earth tide and stored pressure switching valve valve period in wells earth tide. 2. The method according to p. 1, characterized in that for the case when the pressure head of the stream encircling the mineral layer is higher than the level of the surface of the earth, the reservoir with the leaching agent of the injection well is placed so that the bottom of the reservoir is higher than the level of self-discharge by an amount tidal wave amplitudes. 3. The method according to p. 1, characterized in that for the case when the pressure head of the flow encircling the mineral layer is higher than the level of the day surface of the earth, the reservoir for collecting the productive solution of the dispensing well is placed so that its upper part is below the level of self-discharge by the magnitude of the amplitude of the tidal wave. 4. The method according to p. 1, characterized in that the preparation of geotechnological wells for mining in the underground part of the downhole equipment is carried out by perforating the casing in the interval of the thickness of the mineral layer and equipping the perforated sections of the casing with packers that provide selective overflow of working fluids - leaching agent and productive solution - in the bedrock, or in the bottom, or in the middle part of the mineral layer with the implementation of several options Mining of the mining site: from top to bottom, from bottom to top or horizontally in the direction of flow of the flooding layer of a mineral mineral pressure stream. 5. The method according to p. 1, characterized in that the leaching agent used is obtained directly from the field from material from rocks lying on a mineral layer in the surface layer of the earth's interior, for example peat or brown coal.

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