RU2067169C1 - Method for underground leaching of rocky ores in places of their occurrence - Google Patents

Abstract

FIELD: mining industry. SUBSTANCE: method for underground leaching of rocky ores in places of their occurrence includes driving in ore enclosing horizon of draining, injection and compensation workings, supply of leaching solutions to the mass of broken ore from drainage working, and discharge from it of productive solutions. Novelty consists in that drilled from drainage working are holes uniformly distributed on the floor of broken ore, and supplied through holes is air coming from drainage working to the ore mass. EFFECT: higher efficiency. 9 cl, 1 dwg

Description

 The invention relates to mining and can be used in the extraction of non-ferrous and other metals by underground leaching at the site of their occurrence.

There is a method of copper mining by underground leaching at one of the deposits in Nevada (USA), located on a mountainside and consisting of a massive ore body with an area of 90 x 120 m ² and a thickness of 150 m. The method consists in crushing this body by a powerful explosion without moving ore mass, sinking after the explosion of drainage mine workings in its soil, supplying leaching solutions to the surface of the blasted mass and collecting productive solutions in drainage workings (Lutsenko IK and others. Mineless mining is productive deposits, M. Nedra, 1986, p.135).

 The main disadvantages of this method are: the inability to use it for ore deposits extending to great depths from the earth's surface, the low rate of leaching of ores due to weak oxidation processes, the inability to leach in winter, especially in territories with a cold climate, etc.

 The closest in technical essence and the set of essential features to the claimed invention is a method of underground leaching of rock ores used by the company "Kerr Edison Mine" in Canada (Heap and underground leaching of metals, Lisovsky G.D. and others. Ed. Voloshchuk S.N. M. Nedra, 1982, p. 82 85).

 The method consists in conducting compensation, drainage and injection workings in the ore body, crushing ore by explosions into the compensating and partially drainage workings, supplying air to the blasted mass through the drainage working body and discharging it through the working workout, supplying leaching solutions through the working workout by irrigating the surface of the crushed ore and release through drainage production of productive solutions.

 The disadvantages of the method adopted for the prototype are: insufficiently high intensity of leaching of ores associated with uneven air supply and, accordingly, with uneven oxidation of ore in different parts of the blasted mass; the implementation of an excessively large amount of work for sinking of compensation workings and the formation of free volume above the ore surface from compensation workings, arrangement of sites for heap leaching of this ore, subsequent storage of leached ore and related environmental protection measures for adjacent territories, etc.

 The objective of the invention is the creation of a method that provides intensive leaching of ores at minimum cost for its implementation and the maximum preservation of the natural environment in the territory adjacent to the mine developed by this method.

 This problem is solved by creating a method of underground leaching of rock ores at the place of their occurrence, including the excavation of drainage, injection and compensation workings in the ore-bearing horizon, ore crushing by explosions to compensate production, air supply to the crushed massif through the drainage production and its discharge through the discharge production, supply to the same array of leach solutions through the drainage outlet, and, according to the invention, in this method, the air supply from the drainage outlet heel lead through the borehole, evenly distributed in the soil crushed ore.

 According to the invention, the air supply is continuous throughout the entire period of mining blasted array. In this case, it is advisable to start supplying air to the supply of leaching solutions and to supply air in this period with a temperature above the temperature of the crushed array. When the leach solution is supplied, the air supply does not stop and the air flow rate is maintained greater than half the flow rate of the leach solution. After the crushed ore is leached, the drainage and injection workings used for their intended purpose are used as compensation for crushing to leach subsequent volumes of the ore mass.

 According to the invention, it is also advisable to ore extracted from the ore body during the passage of drainage, injection and compensation workings, stored on the surface of the earth at the places where the ore body exits, followed by leaching by leaching solution to the surface of the ore being stored and collecting productive solutions in the downstream drainage mine . It is useful especially in winter, to feed this through wells evenly located on the surface of the stored ore and buried below the depth of seasonal freezing of soils. It is also advisable when forming the volume of stored ore to use barren rock obtained during the excavation of mine workings, for the construction of sides at the boundaries of the ore body, to the surface of the earth.

 The drawing shows a geotechnological scheme for mining the field. A deposit of copper ores is known, starting from the earth's surface and submerging with relatively shallow angles of incidence to a depth of 500,700 m. The vertical thickness of the ore body is about 1 II m, ore-bearing rocks are mainly quartz polyspar silica, low permeability sandstones containing about 1% of the main ore-forming copper in the ore Chalcosine and Bornite are the minerals; the entire deposit is located in the permafrost zone; the duration of the winter period is about 230 days. in a year.

 In accordance with these and others, which are not of fundamental importance in the considered example, the initial mining of the deposit is carried out according to a geotechnological scheme, the main elements of which are shown in the section of the deposit, drawn across the strike of the ore body (drawing).

 The section shows: ore body 1, surface of the earth 2, injection mine 3, passed along the strike of the ore body (all mine workings in this example were also passed along the strike of the ore body); well 4 for venting air from the crushed ore mass, well 5 for supplying leaching solutions to the crushed mass; block 6 with crushed ore; streamline 7 of the leach solution; barren rock mass 8, extracted during mining; waterproofing layer 9 from local clay soils; well 10 for supplying solutions, buried below the seasonal freezing of soils; ore 11, extracted during excavation and stored on the surface of the earth; well 12 for collecting productive solutions; well 13 for supplying air to the array; drainage output 14; compensation output 15; a boundary 16 between the leach blocks; air flow line 17.

 Field development is carried out block by block, starting with its surface parts. To do this, in the near-surface block, compensation workout 15 is carried out and the ore of this block is crushed, using workout 15 as well as space above the surface of the earth as compensation space. Then there are drainage and injection workings 14 and 3 in the downstream block and they are drilled from them through 1 10 m of a well for air supply 13, collection of productive solutions 12, for air removal 4 and for supply of leach solutions 5.

Ore and barren masses obtained during the excavation of mines are stored on the surface of the earth, ore at the places where the ore body exits, and the barren mass beyond the boundaries of the exits, as shown in the drawing. In this case, the ore rock is separated from the barren clay screen from local soils in order to prevent leakage of leaching solutions outside the mining area. The stored ore mass is drilled from the surface by boreholes 10 along a grid, the dimensions of which are determined depending on the height of the stored ore, usually its sizes range from 3 x 3 m ² to 10 x 10 m ² . Wells are cased with pipes with perforated walls to a depth of more than 3 m, i.e. below the boundary of seasonal freezing of soils.

After the top block thus prepared, for leaching, air heated to 50 ^° to 70 ^{° C. is} supplied to it through the drainage outlet 14 and wells 13, based on the calculation of its supply in the amount of about 100 cm ³ per 1 ton of ore, for 1–3 months to thaw the ore and its oxidation. After heating the ore to positive temperatures, the air supply is reduced to 5 m ³ per 1 ton of ore and fed through wells 5 and 10 (in the summer through irrigation spraying apparatus) leaching solutions in the amount of 2 m ³ per 1 ton of ore. The indicated amounts of air and solution are supplied for 1 to 2 years. As a result of this supply, productive solutions are formed with a copper concentration of 4.5 g / l in them, which are collected at the bottom of the well block 12 and then transported through the drainage outlet 14 for further processing by known methods (sorption, extraction, electrolysis, etc.).

 After the specified time, the block is leached to a predetermined recovery level (75–95%) and therefore, they begin to prepare for the subsequent leaching of the downstream block. The sequence and composition of operations remain basically the same as those described above, namely: sinking in the block of compensation workings, and in the next block of drainage and compensation workings below, blasting ore in the block to workings in it, drilling technological wells from an adjacent block along roofing and soil of crushed ore, air supply, leaching solutions, collection of productive solutions.

 After mining this block, these operations are repeated in the block following the ore body fall, and so on until the end of mining.

 Thus, as a result of the method, it is possible to increase the concentration of copper in the solution in relation to the known methods by more than 2 times, respectively, reduce the life of the deposit, minimize environmental damage, reduce the cost of supplying copper and obtain a number of other positive effects .

Claims (9)

 1. The method of underground leaching of rock ores at the place of their occurrence, including sinking in the ore-containing horizon of drainage, injection and compensation workings, ore crushing by explosions to compensate production, supplying leaching solutions to the crushed ore mass from the drainage working out and discharge of productive solutions from it, air supply into the array of crushed ore from the drainage mine, characterized in that wells are drilled from the drainage mine, evenly distributing them over the soil of the crushed ore through which t air from the drain output in an array of ore.  2. The method according to claim 1, characterized in that the air supply is maintained continuously throughout the life of the crushed array.  3. The method according to claim 1, characterized in that the air supply to the crushed array is started before the leaching solutions are fed into it and air is supplied above the temperature of the array.  4. The method according to claim 1, characterized in that the supply of air and leaching solutions is carried out simultaneously.  5. The method according to claims 1 to 4, characterized in that the air supply is conducted with a flow rate in excess of half the flow rate of the leaching solutions.  6. The method according to claim 1, characterized in that the drainage and injection workings, after the end of their use, are used as compensation in preparation for leaching of the ores surrounding them.  7. The method according to claim 1, characterized in that the ore extracted from the ore body during mining in it is stored on the surface of the earth at the places where the ore body exits and is leached by feeding a leaching solution to the surface of the stored ore and collecting productive solutions in the downstream drainage mine.  8. The method according to PP. 1 and 7, characterized in that the supply of solutions is through wells, evenly spaced on the surface of the stored ore and buried below the depth of seasonal freezing of soils.  9. The method according to claims 1 and 7, characterized in that for the construction of the sides when storing the ore mass using barren rock obtained during the excavation of mine workings.