RU2350896C2 - Method for blasting preparation of gold-bearing ore for leaching - Google Patents

Abstract

FIELD: blasting.

SUBSTANCE: method is related to hydrometallurgy and may be used, in particular in leaching of nonferrous, rare and noble metals ores. Method of gold-bearing ore blasting preparation for leaching includes drilling of shot holes, delineation of zones with different level of gold content, installation of explosive charges (EC) in shot holes and blasting of EC. Drilling of shot holes and installation of EC in shot holes is performed differentially in zones. In zones enriched with metal and background zones with specific consumption of EC, which provides for size of disintegrated ores partings required for efficient excavation. In sections transitional between these zones - with increased specific consumption of EC, which provides for effect of dispersed gold microaggregation and formation of developed network of microcracks in ore partings after blasting. Blasting initiation is carried out with short delay in transitional sections relative to enriched and background zones.

EFFECT: increased efficiency of leaching, due to provision of higher microcracking of blasted ore and dispersed gold microaggregation in it, and to increase extraction.

1 dwg, 1 ex

Description

The method relates to hydrometallurgy and can be used, in particular, in preparation for leaching ores of non-ferrous, rare and precious metals.

A known method of explosive preparation of gold-bearing ores for leaching, including drilling wells, placing explosives (BB) in them and their subsequent initiation, which results in their transition to the gas phase and ore destruction (Rzhevsky V.V. M .: Nedra, 1978, p. 53).

The disadvantage of this method is the low recovery of dispersed gold during subsequent leaching, due to the large size of the individual blasted ore mass and low intensity of microcrack development.

The closest in technical essence and the achieved result is the method of explosive ore preparation, in which the calculation of the parameters of the explosion is carried out taking into account the need to ensure the minimum size of the ore for subsequent efficient extraction of metals during underground leaching (see Construction and reconstruction of underground leaching mines. - M .: Nedra 1987, p. 152-155).

The disadvantage of this method is the insufficiently high recovery of gold during subsequent leaching, due to the predominant use of the energy of the explosion to reduce the lumpiness (size of individual parts) of the blasted mass, without significant microstructural transformations of the mineral substance (enlargement of microinclusions of gold).

The technical result of the invention is to increase the efficiency of the process by providing both increased microcracking of the exploded ore and micro-aggregation of dispersed gold in it, which ensures the efficiency of its subsequent leaching and, first of all, increased recovery.

The essence of the invention lies in the fact that in the method of explosive preparation of gold-bearing ores, including drilling blast holes, contouring zones with different levels of gold, placing explosive charges in the wells and blasting charges, drilling wells and placing explosive charges in the wells, they differentiate by zones: in zones enriched with metal and background zones with a specific consumption of explosives that provides the required fineness of disintegrated ores for the effective extraction, and in transitional in these zones, areas with an increased specific consumption of explosives, which ensures the achievement of the effect of dispersed gold microaggregation and the formation of a developed network of microcracks in individual ore after the explosion, and the explosion is initiated with a short deceleration in the transitional sections of the relatively enriched and background zones.

The increase in through extraction of gold from ore subjected to explosive destruction with increased energy impact can be explained by two effects:

1) the development of a network of additional microcracks and pores in the crystal lattice of minerals carriers of dispersed gold, providing respectively more complete access to it of a leach solution;

2) an increase in the size of micro-precipitations of gold in the crystal lattice (from the cluster to the microaggregate level), which increases the likelihood of its contact with microcracks through which the reagent solution penetrates.

The effect of enlargement of microdegradation of gold can be due to the diffusion of gold atoms, caused both by the transfer of impulses to them from the nodes of the crystal lattice deformed during the explosion, and by hydrogen ions (protons) arising from the dissociation of pore water.

The effect of increasing the concentration of atoms of impurity elements in the surface layers of the crystal lattices is confirmed by the data of complex emission spectral analysis of sludge from sulphide minerals formed during prolonged grinding. Based on the results obtained, it follows that it is more efficient to carry out explosive preparation of ores containing dispersed gold with an increased but differentiated specific explosive consumption in zones distinguished by the level of metal concentration.

The method is as follows.

Initially, ore zones with a different level of gold concentration are extracted from the block being prepared based on the data of testing the mineral mass obtained from a borehole survey of a block of the overlying horizon or well logging (geophysical study of wells - logging).

Enriched, background and transition zones are distinguished on the prepared horizon.

In transition zones, the level of dispersion of gold is lower than in enriched ones, where the process of ore genesis was closer to completion.

The contouring of ore blocks on the underlying horizon is carried out in the following sequence. Initially, the areas of influence of samples with a high gold content are combined into the corresponding zones, and then the position of the boundaries of the transition sections between the enriched and background zones is predicted. In this case, two border separating the enriched and background zones are carried out, thereby distinguishing transition zones (see drawing). The contouring process is most efficiently carried out using computer technology according to the developed program.

Blast holes are drilled in accordance with the zones identified at the contouring stage. Blast holes in enriched and background zones are drilled through a network determined by the optimum specific consumption of explosives according to the condition of achieving the required lumpiness, and in transition zones they are drilled through a denser network or (and) with a greater depth, i.e. with a higher specific consumption of explosives than in enriched and background ones.

In the transitional zones, short-blown explosions of the charges placed in them are produced relative to those placed in the background and enriched zones.

Explosion schemes are designed for each specific block in accordance with the morphology of enriched zones, plicative and disjunctive disturbances. Due to a larger number of blast waves passing through the transition zone and a larger average energy value proportional to the number of explosives placed in it, not only a greater degree of ore crushing should be ensured, but also a more significant migration of dispersed gold to the microsurfaces formed and its aggregation. Thus, a more intense loading of transition zones with a high level of dispersion of the gold contained in them is carried out in a clamped medium, and, consequently, a more significant redistribution of dispersed gold in the crystals of carrier minerals with its microaggregation (enlargement) on the formed surfaces.

The methodology for calculating the correcting coefficients of specific explosive consumption by zones and coordinates of wellheads is developed for specific conditions.

An example of a specific application of the method.

When developing deposits of the gold-quartz formation of the stockwork and vein morphostructural types, enriched (more than 5 g / t of gold), background (1.2-3 g / t) and transition zones are distinguished by enumeration (1.2 m). The enriched and background zones are drilled through a 3 × 3 m network, with a well depth of 11.2 m (the step height is 10 m, the steps are 4-6 m depending on the structure of the array), and the transition zones are networked 2.5 × 2.5 m Blast network switching is carried out with the installation of moderators in the transition sections. In an explosion with a short retardation, in this case, the ore is subjected to intense impact in the transition areas, respectively, while it will have an average individual size of the order of 100 mm, increased microcracking and coarseness of gold micro-precipitations.

In addition, after the explosion, there will be an accumulation of gold-quartz aggregates in the smallest fraction, which can be used to isolate the productive class during subsequent screening of the ore.

Claims (1)

The method of explosive preparation of gold-bearing ore for leaching, including drilling blast holes, contouring zones with different levels of gold, placing explosive charges in the wells and explosive charges, characterized in that the wells are drilled and explosive charges are placed in the wells differentially according to zones, in metal-enriched zones and background zones with a specific explosive flow rate, providing the required size for the effective extraction of the size of the units of disintegrated ores, and in transition between zones in areas with an increased specific consumption of explosives, ensuring the achievement of the effect of dispersed gold microaggregation and the formation of a developed network of microcracks in individual ore after the explosion, and the explosion is initiated with a short deceleration in the transition sections of the relatively enriched and background zones.

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