RU2348800C2 - Combined geotechnical method of mining metal ore deposits - Google Patents

Abstract

FIELD: mining.

SUBSTANCE: present invention pertains to mining, particularly to geotechnical methods of mining metals. The combined geotechnical method of mining metal ore deposits involves construction of injection and extraction goaves where the ore body is located, forming a stock pile of ore of the same type, installing a sprinkling system, supplying leaching solutions for sprinkling the stock pile and into injector goaves and outlet of production solutions through a drainage system and raising to the surface through extraction groaves. The production solutions are processed. The processing mother solutions undergo pre-strengthening by a leaching reagent and are returned for leaching. The leaching solutions are supplied through extraction goaves to the place where the ore body lies. The ore stockpiles are sprinkled by solutions raised to the surface through extraction goaves, and the obtained production solutions through the drainage system of the ore stock pile are taken for processing. Protection of underground water and its subsequent reclamation is done through creation of balance weight between volume of production and leaching solutions.

EFFECT: improvement of economic factors and solving arising ecological problems.

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Description

The invention relates to mining, and in particular to geotechnological methods for the extraction of metals.

Methods of metal geotechnology allow, without significant environmental damage, to develop deposits where the content of valuable components is small and production is unprofitable in the traditional way. Such methods include methods of leaching in ore stacks - heap leaching (KB) - and leaching at the ore bed - underground leaching (PV) - using chemical or bacterial solutions.

In the general case, the heap leaching method includes building an impermeable base, forming an ore stack on it, installing an irrigation and drainage system, irrigating the stack with a leach solution, collecting production solutions, processing them, restoring processing solutions with a leaching reagent, and returning them to stack irrigation.

Moreover, there are various options for the intensification of this method at all stages of its implementation. Numerous publications are known on the heap leaching method, which describes the construction methods and technological methods that allow ore to be leached economically (Lisovsky GD et al. Heap underground leaching of metals, M., Nedra. 1981; Heap leaching of precious metals. Edited by M.I. Fazlulina, Publishing House of the Academy of Mining Sciences, 2001, p.19-34).

The PV method includes the construction of injection and pumping openings at the site of the ore body, feeding the leach solution to the pumping openings, raising the production solutions to the surface through the pumping openings, processing them, reinforcing the mother liquors of the mother liquor with the leaching reagent and returning them to leaching. Improvements to this method relate to both minimizing costs, using intensifying factors, and rational use of reagents and optimizing leaching processes (Uranium mining by underground leaching. Edited by V.A. Mamilova, M., Atomizdat, 1980; Kolabin A.I. Useful mining minerals by underground leaching and other geotechnological methods. M., Atomizdat, 1981. Arens V.Zh. Well extraction of minerals. M., Nedra, 1986; Construction and operation of underground leaching mines. share V.N.Mosinets. M., Nedra, 1987.).

When implementing geotechnological methods, the mechanical condition of the rock and ore is taken into account. A necessary condition for high-quality leaching is sufficient ore fragmentation. The ore should not be too large so as not to restrain the rate of leaching, but at the same time not so small as to cause siltation of the selection systems for productive solutions. This takes into account the processes of self-destruction of the rock or artificial fracturing. It is also known that by rational placement of the leach and production solution supply systems, the leach costs can be reduced. It should be noted that a serious problem in the geotechnological methods of leaching metal ores is the prevention of the spreading of leaching solutions through the constructed base at KB and beyond the boundaries of the ore body - with PV.

Closest to the technical nature of the proposed method is the "Method of underground leaching of rock ores at the place of their occurrence" (RF patent No. 2067169, CL ЕВВ 43/28), according to which drainage, injection and compensation workings pass in the ore-bearing horizon, ore is crushed into compensatory production, leaching solutions are fed into the crushed ore mass from the drainage production and productive solutions are released from it.

The disadvantages of the prototype method include the need for blasting, the organization of air supply to the crushed ore. The impossibility of retaining man-made waters in the circuit of the mined ore body and the lack of technical solutions for the remediation of contaminated groundwater.

The problem to which the invention is directed is the development of a comprehensive geotechnological method for mining metal ore deposits, which allows to improve economic indicators and solve emerging environmental problems.

The technical result is achieved by the fact that at the site of the ore body the pumping and injection workings are constructed, a pile of the ore of the same technological characteristics without an impermeable base is formed within the boundaries of the ore body being mined, leach solutions are fed through injection workings at the place of the ore body, and the ore stack is irrigated with the surface through the pumping workings with solutions and the resulting production solutions through the drainage system of the ore stack are sent for processing, while protecting groundwater and their subsequent reclamation is carried out by creating a debapance between the volumes of production and leaching solutions.

The proposed method is as follows.

In the ore body to be mined, a system of injection and pumping openings is constructed at the place of occurrence by drilling pumping and injection wells and sinking infiltration ditches. A pile of ore is formed near or at the site of the constructed wells. As ore using balance ores or dumps of off-balance ores of the same type. During the construction of the ore stack at the site of the pumping and injection wells, it is possible to supply leaching solutions to the injection wells and raising production solutions from the pumping wells to the surface.

In the case of poor filtration of solutions through the underlying stack, the layer is preliminarily removed or the infiltration ditches pass through it, filling them with a well filtering material. If the underlying layer has weak filtration properties to a considerable depth, then injection wells are additionally drilled in the infiltration ditches, equipped with airlifts for periodic pumping in order to maintain injectivity, and the mouths of the injection wells and infiltration ditches are covered with well filtering material.

According to another technical solution, the injection wells additionally drilled in the infiltration ditches are connected by perforated drainage pipes laid in a bed underlying the ore stack.

The mining of the ore body and the ore stack built on it is carried out sequentially:

leaching solutions through injection wells or infiltration ditches are fed into the ore body at the place of occurrence, solutions containing the recoverable element are lifted through the pumping wells and fed to the ore stack for irrigation. The resulting production solutions through the drainage system of the stack are taken out for processing, the mother liquors of the processing are reinforced with a leaching reagent and sent to injection wells or infiltration ditches.

The undoubted advantage of the proposed combined geotechnological method of leaching is the absence of the need to construct an expensive and labor-intensive impermeable base under the formed ore stack with guaranteed protection of the underground water involved in the circulation and their subsequent reclamation. Such protection is carried out by creating a debapance between the volumes of production and leaching solutions by organizing the evaporation of part of the solutions supplied for irrigation of the ore stack. Evaporation is carried out, for example, by evaporation, by creating ponds-evaporators, spraying through nozzles under pressure, feeding into cooling towers with natural or forced ventilation, as well as by other methods allowing to intensify the evaporation process. This, in turn, leads to the creation of a depression funnel that prevents the spreading of contaminated groundwater beyond the contours of the ore body.

Another advantage of the proposed method is the possibility of involving in the processing of dumps of off-balance and technogenic homogeneous ores, which improves the economic performance of mining. In addition, this method with minimal costs allows you to vary the performance of the production solution (pH and Eh) in wide intervals, choosing the method of their processing and the final type of product.

The possibility of implementing the proposed method is illustrated by the following example.

Example. In laboratory conditions, a leaching plant for the balance and off-balance oxidized copper ore of one of the deposits was assembled.

Oxidized copper ore containing 0.9% copper was placed in the reservoir model simulating the ore body at the place of occurrence, and off-balance copper ore from old-time dumps with a copper content of 0.07% and currently unused was placed in a percolator simulating an ore stack .

Leaching was carried out with a solution of sulfuric acid. The leach solution was fed into a filter tube simulating a reservoir model, and then from it into a percolator. The concentration of acid in the leach solution at the outlet of the reservoir model of the formation and the value of W: T in simulating heap leaching were determined in preliminary experiments. At the same time, leaching of oxidized copper ore in comparable conditions was carried out in another filter tube. The results of the experiment showed that at the same acid flow rate according to the proposed method, the degree of development of the proposed conditional deposit increased by 20.2%, and a small amount of impurities that went into the solution made it possible to extract copper from production solutions with high technological parameters.

Thus, the above description of the embodiments of the proposed method and example show the possibility of implementing a combined geotechnological method for mining metal ore deposits.

Claims (1)

A combined geotechnological method for mining metal ore deposits, including the construction of injection and pumping openings at the ore body, the formation of a pile of the same type of ore above it, the installation of a stack irrigation system, the supply of leach solutions for stack irrigation and injection workings, through the drainage system and uphill surface through the pumping out of production solutions, their processing, additional strengthening of the mother liquors of the processing with the leaching reagent and their return to the leach characterized in that the leaching solutions are fed through injection openings at the ore body location, the ore stack is irrigated with solutions raised to the surface through the pumped excavations, and the resulting production solutions are sent through the drainage system of the ore stack for processing, while protecting the underground waters and their subsequent reclamation carry out the creation of an imbalance between the volumes of production and leaching solutions.