RU2018139445A - Ecological geotechnology development of iron ore deposits - Google Patents

Claims (88)

1. Ecological geotechnology for the development of iron ore deposits by means of underground leaching of useful ore components by drilling production wells through the network formed by parallel rows of wells drilled in the direction of the flow of the flooded mineral fossil flow, preparing wells for mining the mineral by attaching to the wellhead of each well tanks equipped with shut-off and control valves, injection of leaching agent into the reservoir Mineral fossil, dissolving mineral components of ores with the formation of a productive solution, dispensing the obtained productive solution to the surface, supplying the liquid leaching agent to the reservoir of the mineral and discharging the productive solution to the surface using a regular daily action of the tidal wave of the earth surface above the deposit by activating the dispensing valve valve in the period of the earth's high tide and the inclusion of the injection valve in the period of earth ebb, different It means that before starting the development of a field, a geotechnological model of field operation is created on the basis of available information on the field’s natural resources, which is corrected during the field’s exploitation, on the basis of which the structural design of each production cell of the network and its operation mode are determined, and the production cell of the network is formed by one universal operational a well containing a large vertical borehole drilled to the bottom of the reservoir with the equipment of the supporting poppy from hardening material, having a conductor above the top of the productive formation, through which the productive formation in lateral direction is drilled by horizontal small-diameter trunks for pumping leaching agent and producing a productive solution, and the wellhead at the surface is equipped with a reservoir covered with a non-freezing peat layer and containing two tanks - the lower and the upper, and the lower tank is designed for collecting, storing and pumping a leaching agent into the reservoir, as Tve of which is used swamp water from peat deposits overlying the deposit, and the upper tank is designed to collect productive solution and extract useful ore components from it, while both tanks are equipped with autonomous monitoring and measuring devices and regulating devices that allow remote control and management of mining network cells universal production wells. 2. The method according to p. 1, characterized in that the geotechnological model of field exploitation is created on the basis of previously explored and updated in the process of field development information about the geological conditions of occurrence in the depths of the earth the mineral. 3. The method according to p. 1, characterized in that the geotechnological model of the exploitation of the field is created on the basis of previously explored and updated in the process of developing the field information about the hydrological conditions of the underground and surface waters. 4. The method according to p. 1, characterized in that the geotechnological model of the exploitation of the field is created on the basis of previously climatological and meteorological factors that were previously explored and updated in the course of the field development. 5. The method according to p. 1, characterized in that the injection horizontal shafts of small diameter are drilled against and across the direction of the flow that surrounds the formation of the mineral fossil pressure flow. 6. The method according to p. 1, characterized in that the dispensing horizontal shafts of small diameter are drilled in the direction and crosswise of the direction of flow that surrounds the reservoir of the mineral fossil pressure flow. 7. The method according to p. 1, characterized in that the large-diameter vertical shaft of a universal production well is cased from the mouth to the bottom of the reservoir with a thick-walled tube of durable strong acid-alkali-resistant material, for example, plastic. 8. The method according to p. 1, characterized in that the horizontal trunks of small diameter universal production wells are lined with tubes of durable flexible acid alkali resistant material, for example, plastics. 9. The method according to paragraphs. 1, 8, characterized in that the casing of horizontal shafts of small diameter, as they produce the upper layers of the reservoir, first become inclined-horizontal, and in the final stage of the development of the lower layers of the reservoir, bend, become inclined and directed quasi-orthogonal to the direction of the stream that surrounds the reservoir fossil pressure stream. 10. The method according to paragraphs. 1, 8, 9, characterized in that the casing of horizontal shafts of small diameter are perforated from the free end of the pipe for a pipe length equal to the thickness of the mineral reservoir. 11. The method according to paragraphs. 1, 8, 9, 10, characterized in that the perforation of the walls of the casing of horizontal shafts of small diameter is made at an angle of 45 ° to the pipe axis, providing ejection capture leaching agent by passing, overlying the mineral fossil flow stream and creating additional pressure when producing productive solution in the team capacity. 12. The method according to p. 1, characterized in that the mouth of the reservoir is made of durable durable acid alkali-resistant material with a hermetic separation of the lower and upper containers. 13. The method according to paragraphs. 1, 12, characterized in that the lower capacity of the wellhead reservoir is located with its upper edge at or below the foot of the peat bog sediments, and the lateral surface of the lower reservoir is surrounded by drainage-collecting sump of the bog waters. 14. The method according to paragraphs. 1, 12, characterized in that the lower capacity of the wellhead tank is placed with its upper edge at the level of the day surface, and the upper part of the side surface of the upper container is equipped with drains in the form of perforated small diameter pipes, while the upper container is provided with a removable sealed cover. 15. The method according to p. 1, characterized in that the development of iron ore deposits start from the side from which the flowing reservoir of the mineral fossil pressure flows out, then continue to work in the direction of flow of this stream and complete the process at the side in which the flowing water enters . 16. The method according to paragraphs. 1, 15, characterized in that they carry out a uniform and uniform movement of the front of the bottom of the underground mining in the lateral direction, and the thickness of the mineral reservoir - from the roof to the bottom. 17. The method according to paragraphs. 1, 16, characterized in that produce remote control of the physical and chemical parameters of the process of underground leaching in the interacting mining cells of the network. 18. The method according to claim 1, characterized in that the mining process is organized by circulating an aqueous working solution, which purposefully and periodically changes its properties at different stages of geotechnology, namely, first, the swamp water from surface peat deposits accumulates in the lower reservoir of the wellhead reservoir, then Every day, during earth tides, it is fed from the lower reservoir through a vertical borehole of a large diameter and horizontal trunks of small diameter into the reservoir of the mineral where mixing Being with a stream that leads to a reservoir, it has a leaching effect on iron ore and turns into a productive solution, which, every day, during the tide of the earth, is discharged along horizontal and vertical trunks of small diameter into the upper reservoir of the wellhead, where it is extracted from metals the water is drained to the non-freezing surface of the peat deposit in the vicinity of the wellhead and, passing through the entire thickness of the peat deposits, again becomes marsh water, which again emulated in the lower reservoir of the wellhead reservoir and enters the mining process. 19. The method according to paragraphs. 1, 18, characterized in that the extraction of useful components from the productive solution is carried out in a priority order determined regularly at the next stage of field development based on the need for a specific useful component of iron ore, namely, first, the most valuable during the current period of time is extracted component, then, in descending order of value, selectively extract the remaining useful components, if it turns out that selective extraction using hydrometallurgy useful components are inefficient, the productive solution, after extracting the most valuable useful component, as an intermediate product, is sent to obtain a collective concentrate of useful components for the subsequent selective extraction of useful components by other methods, while the intermediate product is concentrated and stored near the mouth of the universal production well. 20. The method according to p. 19, characterized in that the concentration of the intermediate product is carried out through an evaporation process according to the patent RU 2600229 C2. 21. The method according to p. 19, characterized in that the concentration of the intermediate product is carried out through the freezing process according to the patent RU 2600229 C2. 22. The method according to paragraphs. 1-4, 16, 17, characterized in that the remote control of the mode of operation of the mining cell of the network of universal production wells is carried out by controlling the concentration of the leaching agent in the reservoir of the mineral. 23. The method according to p. 22, characterized in that the swamp water is strengthened with a liquid concentrate of local microflora, which disseminates the swamp water. 24. The method according to p. 22, characterized in that the marsh water is strengthened with a liquid concentrate of humic acids obtained from local marsh waters and / or from extracts of local peat deposits. 25. The method according to p. 22, characterized in that the swamp water is strengthened by bubbling the aqueous solution collected in the lower tank of the wellhead reservoir with an acid-forming gas. 26. The method according to p. 25, characterized in that the quality of the gas using compressed chlorine. 27. The method according to p. 25, characterized in that the quality of the gas using compressed sulfur dioxide. 28. The method according to p. 25, characterized in that the quality of the gas using compressed nitrogen dioxide. 29. The method according to paragraphs. 1, 25-28, characterized in that the compressed gas used is used to create a counter-pressure during the ejection of the leaching agent into the pressure stream flooding the mineral reservoir. 30. The method according to paragraphs. 1-4, 16, 17, characterized in that the remote control of the mode of operation of the production network of universal production wells is carried out by regulating the pressure in the lower and upper tanks of the wellhead reservoir. 31. The method according to p. 30, characterized in that the rarefaction of atmospheric air in the upper tank of the wellhead tank is created by means of a vacuum cylinder, which is opened as needed. 32. The method according to p. 30, characterized in that the increased pressure of atmospheric air in the lower tank of the wellhead reservoir is created by means of a cylinder with compressed air, opened as needed. 33. The method according to p. 30, characterized in that the pressure in the tanks of the wellhead tank is regulated by pumping air from one tank to another with an air pump. 34. The method according to p. 33, wherein the air pump is driven by wind energy. 35. The method according to p. 33, wherein the air pump is driven by solar energy. 36. The method according to paragraphs. 1-4, 16, 17, characterized in that the remote control of the mode of operation of the production network of universal production wells is carried out by controlling the temperature of the leaching process. 37. The method according to p. 36, characterized in that produce heating marsh water in the lower tank wellhead. 38. The method according to p. 37, characterized in that for heating is used directly solar heat, captured on the surface, accumulated and transferred by the coolant into the volume of swamp water. 39. The method according to p. 37, characterized in that for heating use thermoelectric heating elements placed in the volume of swamp water, consuming electricity from solar panels. 40. The method according to paragraphs. 37, 39, characterized in that the heat-electric heating elements consume energy from the wind power installation. 41. The method according to p. 37, characterized in that for heating the bog water use the heat obtained in the process of burning peat, the surface deposits of which overlap the iron ore deposit. 42. The method according to p. 37, characterized in that to heat the swamp water using the heat produced in the process of slow chemical oxidation of peat. 43. The method according to p. 37, characterized in that to heat the swamp water use the heat produced in the process of slow microbiological decomposition of peat. 44. The method according to p. 37, characterized in that produce heating of the mineral reservoir. 45. The method according to paragraphs. 36, 44, characterized in that to heat the reservoir using the heat of underground thermal waters. 46. The method according to p. 45, characterized in that the formation is heated from the side of the waterproof roof. 47. The method according to p. 45, characterized in that the formation is heated from the side of the waterproof sole. 48. The method according to p. 45, characterized in that the reservoir is heated directly by mixing thermal water with a pressure flow enclosing the formation. 49. The method according to paragraphs. 44-48, characterized in that a large vertical borehole is drilled from the base of an iron ore formation to the aquifer of thermal waters, planted and equipped with packers below the base, at the level of the base and roof. 50. The method according to claim 1, characterized in that the extraction of useful components of the ore extracted from the productive solution from the upper tank of the wellhead components is carried out mainly from the air by appropriate air devices, for example, remote-controlled robotic complexes such as DRON, helicopters, airships. 51. The method of claim 1, wherein the remote monitoring and control of the operation of the production cells of the network of universal production wells is carried out by means of near-earth space-based, for example, satellite constellation and / or habitable orbital station. 52. The method according to p. 51, characterized in that produce monitoring of changes in the landscape and topography of the surface of the iron ore deposits during the entire time of its development and in the post-exploitation period. 53. The method according to p. 1, characterized in that produce a comprehensive regional monitoring of the natural environment before, during and after the development of iron ore deposits. 54. The method according to paragraphs. 1, 44-49, characterized in that an organic substrate disseminated with methane-generating bacteria is added to the composition of the swamp water supplied to the underground space; the resulting mixture is sent to a heated mine excavation heated to a temperature of 28–40 ° C; the generated methane is released as a gas and / or as part of the gas phase of aerated liquid into the hermetic upper reservoir of the wellhead, and from there it is taken. 55. The method according to p. 54, characterized in that the organic substrate is produced from renewable biological resources that are in demand in the territory of the field being developed and in its vicinity. 56. The method of claim 54, wherein peat is used as a renewable biological resource. 57. The method according to p. 54, characterized in that as a renewable biological resource use wood waste from forest use resulting from sanitary logging for forest care and wood harvesting. 58. The method according to p. 55, characterized in that wood waste wood is used as a renewable biological resource. 59. The method of claim 55, wherein the waste of livestock production is used as a renewable biological resource. 60. The method of clause 55, wherein the crop waste is used as a renewable biological resource. 61. The method of claim 55, wherein the food industry waste is used as a renewable biological resource. 62. The method according to p. 55, characterized in that as a renewable biological resource use organic waste from the chemical industry. 63. The method according to p. 55, characterized in that the solid phase of the organic substrate is crushed to a particle size of less than 30 micrometers. 64. The method according to p. 54, characterized in that the base part of the contaminant consists of methane-generating bacteria of local marsh systems in the territory of the field being explored and its surroundings. 65. The method according to p. 54, characterized in that the methane, after its removal from the wellhead tank, is subjected to comprehensive preparation for transportation and use. 66. The method according to p. 65, characterized in that the gas is purified from mechanical impurities. 67. The method of clause 65, wherein the gas is dried. 68. The method according to paragraphs. 65-67, characterized in that the gas is compressed. 69. The method according to paragraphs. 65-67, characterized in that the gas is liquefied. 70. The method according to paragraphs. 65-67, characterized in that the gas is transported by pipeline. 71. The method according to p. 70, characterized in that the gas is transported by pipeline according to the technical solution RU2001107220. 72. The method according to paragraphs. 65-69, characterized in that the gas is transported in cylinders. 73. The method according to paragraphs. 65-69, characterized in that the gas is transported in tanks by land, water and air transport. 74. The method according to paragraphs. 65-68, characterized in that the gas is transported in soft air-floating shells. 75. The method according to paragraphs. 65-68, 74, characterized in that gas is used at the field according to the technical solution EN 19812 U1. 76. The method according to paragraphs. 65-69, characterized in that the gas is used to produce electricity, including directly at the field. 77. The method according to paragraphs. 65-69, characterized in that the gas is used for heat production, including directly at the field. 78. The method according to paragraphs. 65-69, characterized in that the gas is used for the production of chemical products. 79. The method according to paragraphs. 1, 54, 55, characterized in that at the beginning of the mining operations, geotechnology is implemented by generating a productive iron-containing solution, then in the resulting mine workings they begin to generate methane in parallel with the production of a productive solution, and after mining the entire iron-bearing formation, methane is generated in the entire volume working out. 80. The method according to paragraphs. 1, 54, 55, characterized in that a mineral sediment is formed in the basement space of the mine workings. 81. The method according to paragraphs. 1, 54, 55, characterized in that an organic sludge is formed in the basement space of the mine working, proper above the mineral sludge. 82. The method according to paragraphs. 1, 54, 55, 80, 81, characterized in that they form an organomineral sediment of silt-sapropel type. 83. The method according to p. 82, characterized in that by means of downhole hydraulic extraction of organic-mineral sediment on the surface of the sludge-sapropel substrate. 84. The method according to p. 83, characterized in that mixing the silt-sapropel substrate with an organic substrate and peat get the soil. 85. The method according to p. 83, characterized in that mixing the silt-sapropel substrate with the organic substrate and peat receive fertilizer. 86. The method according to p. 85, characterized in that they receive liquid fertilizer. 87. The method according to p. 85, characterized in that they obtain granular fertilizers. 88. The method according to paragraphs. 1, 54, 79, 82, characterized in that the environmental geotechnology of the iron ore deposit development is implemented cyclically, in the first cycle, using the underground leaching of iron ore, its useful components are obtained as a marketable product; in the second cycle, the commercial gas is received as an energy gas through the underground generation of methane , chemical raw materials and motor fuels, in the third cycle, by means of underground formation of a silt-sapropel substrate, commercial product is obtained in the form of high-quality organoids cial fertilizers.