RU2497962C1 - Method to extract dispersed gold from refractory ores - Google Patents

Abstract

FIELD: mining.

SUBSTANCE: method includes drilling of blast holes in an ore deposit, analysis of drilling sludge, delineation according to results of this analysis of zones, charging of wells by formation of explosive charges in them with differentiated specific consumption of explosives along dedicated zones. Then charges are exploded with ore disintegration and formation of cracks in the ore, leaching of gold from exploded ore by means of irrigation with leaching solutions of reagents and discharge of product solutions. At the same time the wells in zones with finely disseminated ore minerals and dispersed forms of gold location along a compacted network. Besides, in the central part of zones, when explosive charges are formed in them, they arranged containers that are coaxially built into each other with concentrated solutions of two types of reagents that form during mixing with explosive gases a highly active reaction mixture for oxidation of ore matrices that include dispersed gold. Explosion of the specified charges is carried out with moderation relative to explosive charges placed in wells that are drilled in zones with a vein nature of mineralisation and row shot, for formation of the highly active reaction mixture, which is injected into cracks by gases that are produced during explosion of explosive charges.

EFFECT: increased withdrawal of dispersed gold due to growth of efficiency of explosive treatment of ores for leaching.

1 ex

Description

The invention relates to the mining industry and can be used for leaching gold from ores.

There is a method of developing ore deposits, which consists in drilling blast holes in an ore deposit, analyzing drill cuttings, delineating, according to the results of this analysis, zones with different patterns of dissemination, sizes of ore minerals, loading wells with explosives (HE) with differentiated specific consumption of explosives in the selected zones, blasting charges with ore disintegration, leaching of blasted ore by irrigation with leaching solutions of reagents (see Construction and reconstruction of underground mines in leaching. M., Nedra, 1987, p. 152-170).

The disadvantage of this method is the low efficiency of the preparatory processes before leaching gold from ores, leading to insufficient extraction of gold, due to the low degree of activation of the free surfaces of microcracks and pores formed during explosive preparation of ore to leach gold from it, in the composition of finely disseminated minerals or prisoner in them in dispersed forms.

The technical result of the proposed invention is to increase the efficiency of the gold extraction process by explosively forming a network of microcracks in the ore, feeding active concentrated solutions through them, partially oxidizing and leaching gold from their contact layers and enlarging dispersed gold deposits.

The result is achieved by the fact that the method of extracting dispersed gold from refractory ores includes drilling blast holes in an ore deposit, analyzing drill cuttings, delineating zones with different patterns of dissemination, sizes of ore minerals and gold clusters enclosed in them, charging wells with forming them explosive charges (explosives) with differentiated specific consumption of explosives in the selected zones, blasting charges with ore disintegration and the formation of microcracks in the ore, leaching gold from blasted ore by irrigation with leaching solutions of reagents and the release of productive solutions, while wells in areas with finely disseminated ore minerals and dispersed forms of gold are drilled through a densified network, and in the central part of the zones, when explosive charges are formed in them, they are placed coaxially embedded into each other containers with concentrated solutions of two types of reagents, which when mixed with explosive gases form a highly active reaction mixture for the oxidation of ore matrices, including di spherical gold, the blasting of these charges is carried out with a slowdown relative to explosive charges placed in wells drilled in areas with streaky mineralization and ordinary impregnation to form a highly active reaction mixture that is injected into the cracks by the explosion of explosive charges.

As a result of the implementation of the method, a highly active reaction mixture is formed, which is injected by the gases generated during the explosion of explosive charges into the cracks created by the passage of elastic blast waves initiated by the advanced explosion of charges with continuous filling of explosives, which ensures intensive oxidation of ore minerals and leaching of gold from them.

The method is as follows.

Initially, ore zones with a different character of mineralization are extracted from the prepared block based on data from testing drill cuttings or core testing. Zones with predominantly finely disseminated ore minerals and dispersed forms of gold occurrence and zones with a streaky mineralization character and ordinary dissemination on the horizon planned for development are distinguished.

Wells are drilled in the designated areas, which are then charged with explosives. In wells drilled through a compacted network in areas with finely disseminated ore minerals and dispersed forms of gold, in the central part of explosives of the first type, containers (one inside the other) are coaxially placed, for example, in the form of plastic tubes filled with concentrated solutions of two types of reagents, which, upon subsequent mixing with explosive gases, form a highly concentrated active reaction mixture. In areas with a streaky mineralization character and ordinary interspersed wells, explosives of the second type are charged using conventional technology.

When carrying out explosions, a short delay in the initiation of charges of the first type relative to the explosive charges of the second type is provided. An explosion of explosive charges of the second type ensures the formation of elastic deformation zones with growing microcracks in the array, including in zones with finely disseminated ore minerals and dispersed forms of gold. An explosion of charges with reagent containers placed in them in these zones ensures the mixing of these reagents under high pressure and with a rapidly increasing temperature, which leads to the formation of a highly reactive reagent medium containing, in addition to complexing agents for gold, active radicals and ions that contribute, with subsequent penetration into ore material through microcracks, the rapid oxidation of matrices including dispersed gold of minerals and its transformation into a dissolved state. In addition, due to the solid-phase diffusion of gold atoms scattered in the crystal lattice of ore minerals to their surfaces, gold is accumulated and enlarged at the boundaries with microcracks, through which their active interaction with reagent solutions is ensured. Thus, in the proposed method, even before irrigation of the ore disintegrated by the explosion with a solution of a leaching reagent, it is mainly carried out the conversion of dispersed gold into a migratory active state, hydrogeochemical connection through a system of formed microcracks and pores with the main flow of the working solution, which generally provides a significant increase the completeness of the extraction of gold.

An example of a specific application of the method.

Development of lower shock hazardous horizons of the Darasunskoye deposit of gold-sulfide-quartz formation of vein morphostructure type. Ores are refractory, contain a large amount of arsenopyrite and sulfosalts, are characterized by a thin impregnation of ore minerals with dispersed gold and a significant proportion of “thin” gold in quartz and tourmaline. According to the proposed method, gold is leached in a layer-by-layer descending breaking of ore layers, according to the results of drilling holes (0.25 m) of the previous beaten layer, enriched (more than 5 g / t of gold) and background (1.2-3 g / t ) and transitional ore zones with finely disseminated gold and the presence of its dispersed forms in sulfide minerals, quartz and tourmaline. The enriched and background zones are drilled through a 1 × 1 m network with a hole depth of 2.5 m, and transitional zones are drilled through a network of 0.75 × 0.75 m. Holes of increased diameter (75 mm) in the transition zones are charged with explosive charges, in the center of which plastic thin-walled tubes with a diameter of 25 mm are placed with a solution of sodium hypochlorite, which also contains gas bubbles - chlorine and hydrogen, formed during the electrochemical preparation of the solution. In turn, plastic tubes with a diameter of 15 mm with a 1.5% hydrochloric acid solution prepared on the basis of anolyte are inserted into tubes with a hypochlorite solution. The tubes are sealed from the ends. The blast network is switched with the installation of moderators in the transition sections. In an explosion with a short deceleration of charges with reagents relative to charges of a conventional design, first there is an intensive development of microcracks in the ore in transition sections, then, in the explosion of charges of the second stage, hot leaching solutions containing hypochlorous acid formed as a result of the reaction between sodium hypochlorite are injected into them and hydrochloric acid under high pressure explosive gases. Hypochlorous acid in combination with other active ion-radical compounds of chlorine, hydrogen and oxygen, formed during the explosion-initiated reaction between the components of the solutions placed in the tubes, provides intensive oxidation of sulfide-arsenide matrices and the formation of soluble gold-chloride complex anions upon penetration of the solution inside minerals containing dispersed (nanoscale) and “thin” (micron) gold. In this case, the gold-chloride complexes remain in the pore solutions inside the matrices and are discharged into working solutions, which are formed when all layers within the block are blasted off, followed by irrigation of ore in its contours from the drift of the upper horizon with an acidified sodium hypochlorite solution. Working solutions are collected in sumps of the drainage drift, passed in the bottom of the block, periodically analyzed for gold content, pumped to the irrigation horizon and again fed through the drift of the upper horizon to the beaten and magnezed ore, until the metal concentration required for sorption is reached in them.

Claims (1)

A method for extracting dispersed gold from refractory ores, including drilling blast holes in an ore deposit, analyzing drill cuttings, delineating zones with different patterns of dissemination, sizes of ore minerals and gold clusters contained in them, charging wells with forming charges of explosives in them (EX) with a differentiated specific consumption of EXPLOSIVES over the selected zones, the explosion of charges with the disintegration of the ore and the formation of cracks in the ore, the leaching of gold from the exploded ore by growth by leaching solutions of reagents and the release of productive solutions, while wells in areas with finely disseminated ore minerals and dispersed forms of gold are drilled through a compacted network, and in the central part of the zones, when explosive charges are formed in them, containers with concentrated solutions of two solutions are placed coaxially integrated into each other types of reagents that, when mixed with explosive gases, form a highly active reaction mixture for the oxidation of ore matrices, including dispersed gold, blasting is indicated charges are produced with deceleration relative to explosive charges placed in wells drilled in areas with streaky mineralization and ordinary impregnation to form a highly active reaction mixture that is injected into the cracks by the explosion of explosive charges.