RU2457330C1 - Method for re-development of gravel deposits - Google Patents

Abstract

FIELD: mining.

SUBSTANCE: method includes backfill in worked-out area of small-grain dump and further backfill of pebble dump on its surface using mined rock removed upon processing of solid placer and consequent extraction of material from dump removing particles of gold. Before re-processing of dump works for coarsening of gold particles sizes are performed. Before backfill of pebble dump silt-settling tank is formed in near-bedrock part of small-grain dump, for which purpose a barrier is formed on bedrock surface from water-proof, covering perimeter small-grain dump. After backfill of pebble fraction on surface of small-grain dump, dump is exposed during the time interval required for flushing of dump space by non-ramming water flows, then the dump is frozen preferably in two stages. Upon extraction of material from the dump its volume located above volume of silt-settling tank is removed without flushing. In order to flush volume of the dump by non-ramming water flows, natural water-borne sediments and/or forced feed of water to the dump surface is used. During formation of water-proof barrier water-proof film material is used in addition.

EFFECT: higher gold extraction efficiency during re-development of gravel deposits.

5 cl, 3 dwg

Description

The invention relates to the mining industry and can be used in the development of reserves of man-made placers formed during the mining of whole gold placers.

Man-made placers are a complex combination of dump formations characterized by a chaotic distribution in their thickness of particles of precious metals and natural placers not worked out during their initial operation.

The main resource and technological features of man-made placers that determine the low economic efficiency of their further processing include:

- a relatively low content of useful components (gold) in the dumps of technogenic formations;

- a significant proportion of gold of fine and fine fractions, in comparison with fractions of the whole structures of natural placers, which necessitates the use of special, more complex technologies for its extraction, in the processing of technological dumps.

Therefore, in the development of technogenic formations, technological processes are of fundamental importance, providing preliminary preparation of the rock mass for enrichment, which have a direct impact on improving the efficiency of both traditional enrichment apparatuses and new equipment.

Known methods for re-dredging the development of placers using dredges and excavation equipment, where after working out each section of the deposit as a whole placer, dump peat from the next section (see SU No. 1097797, Е21С 45/00, Е21С 41 / 00, 1984 and SU No. 1263849, Е21С 41/00, Е21С 45/00, 1986).

The disadvantage of these methods is the gross dredging of conditioned and substandard layers of pebble-epile dumps, which sharply reduces the content of useful components in the washed rock mass, increases the technological losses of gold and makes the re-development of man-made placers, as a rule, unprofitable.

There is also a method of re-development of alluvial deposits, including dumping in a mined-out space of an epiline dump and subsequent dumping on its surface of a pebble dump using rock mass extracted during mining of a bulk placer, and subsequent excavation of the material of the dump with the extraction of gold particles (see RU 2024753, E21C 41/26, 1994).

The disadvantage of this method is the low efficiency of gold extraction due to the fact that thin gold, which often constitutes a significant part of its placer reserves, is very difficult to extract, especially with a significant variation in the parameters of gold (gold particles) that determine their hydraulic fineness.

The problem to which the claimed solution is directed is expressed in increasing the efficiency of gold extraction during the re-development of alluvial deposits. The technical result obtained by solving the technical problem is expressed in providing a preliminary concentration of gold-containing fractions in the near-flood area of the dump, which minimizes the volume of washed rock mass. In addition, it is possible to sorption the merging of gold particles due to the use of high pressures in the volume of the sludge tank, developed during its freezing, thereby enlarging them, which ensures sufficiently efficient extraction.

To solve this problem, the method of re-development of alluvial deposits, including dumping in the worked-out space of an epiline dump and subsequent dumping of pebble dump on its surface, using rock mass extracted during mining of the whole placer, and subsequent excavation of the material of the dump with the extraction of gold particles, differs in that before re-mining the dump, work is underway to enlarge the size of the gold particles, while before dumping the pebble dump in the near-epic part a dump sludge is formed, for which a barrier is made on the surface of the raft from a waterproof, for example, clay material, covering the perimeter of the epic dump, and after dumping the pebble fraction onto the surface of the epic dump, the dump is kept for the time necessary to wash the dump volume with non-pressure water flows , then carry out freezing of the blade, preferably using natural cold, preferably in two stages, starting with the volume of the blade except for the sludge nick which freezing is carried out in the last instance, in addition, when removing the blade material, its volume is situated above the silt-settling tank volume is removed without washing. In addition, before excavation of the rock mass, freezing of the blade is carried out repeatedly. In addition, in the process of freezing the upper part of the blade, it is additionally moistened. In addition, for washing the volume of the dump with non-pressure water flows, natural precipitation and / or forced supply of water to the surface of the dump are used. In addition, when forming a waterproof barrier, a waterproof film material is additionally used.

A comparative analysis of the set of essential features of the proposed technical solution and the set of essential features of the prototype and analogues indicates its compliance with the criterion of "novelty".

In this case, the essential features of the characterizing part of the claims solve the following functional tasks.

The signs “before re-mining the dump carry out work on enlarging the size of the gold particles” make it possible to “remove” the gold-containing particles from the thin gold category into larger fractions, which, in turn, allows the extraction efficiency of which to be significantly higher.

The signs “before dumping the pebble dump, form a sludge trap in the near-flat part of the ephevel dump” provide the possibility of creating a “reservoir” of thin gold in the lower zone of the dump due to washing of its overlying volume with pressureless water flows and further provide the possibility of creating high pressure in the volume of the sludge trap.

The signs “on the surface of the raft create a barrier from a waterproof, for example, clay material, covering the perimeter of the epic dump” provide the formation of a sludge tank, as a tank hydraulically isolated from the rest of the space.

The signs “after pouring the pebble fraction onto the surface of the epiline dump maintain the dump during the time necessary for washing the dump volume with non-pressurized water flows”, the gold-containing fraction is moved from top to bottom into the sludge tank, since the permeability of the pebble and epic components of the dump is quite large (pebble size varies from 16 to 80 mm, a density ρ of 1800 to 2500 kg / m ^3, the proportion of pebble fraction in the total weight of rocks from 5 to 50%; Ephel size of less than 50 mm, a density of from 1750 to 2150 kg / m ^3, the proportion of coat efelnoy uu total weight species of 15 to 95%). In this case, a sludge fraction is formed, with the size of the efel less than 2 mm (its share is 10-45% of the mass of the dump rocks).

The signs “carry out freezing of the blade” provide both increased migration of the gold fraction down to the sludge trap, and further enlargement of gold particles due to their cohesion with each other.

Signs indicating the preference for the use of "natural cold", eliminate the cost of freezing-cooling the blade.

Signs indicating the preference for freezing the blade "in two stages, starting with the volume of the blade with the exception of the volume of the sludge tank, the last freezing of which is frozen", allows to increase the level of pressure developed in the volume of the sludge tank, since they ensure the process is carried out as if in a cavity " ice capsule. "

The signs “when removing the material of the blade, its volume located above the volume of the sludge tank is removed without washing” provide a reduction in the cost of washing the material of the blade by reducing the volume of the washed material. The signs of the second claim allow to increase the yield of the enlarged gold-containing fraction.

The signs of the third claim make it possible to increase the strength of the blade volumes frozen at the first stage.

The features of the fourth claim make it possible to increase the washing efficiency of the dump volume with pressureless water flows (washing out and migration of gold particles downward), especially at low levels of natural water precipitation.

The features of the fifth claim allow to increase the water resistance of the waterproof barrier.

The claimed invention is illustrated by drawings, where figure 1 shows a cross section of a blade; figure 2 - schematically shows a longitudinal section of a blade with a cooling-heating sludge tank; figure 3 shows the nature of the distribution of gold after 21 cycles of "frost-thawing".

Processing of man-made dumps may be appropriate while ensuring a high concentration of the remaining finely divided fractions of gold in the lower layer of the epiline dump and in the sludge tank. The main amount of gold in the man-made placer is represented by small and very small classes of fineness (from 0.06 to 0.5 mm). There is a clear pattern of an increase in the amount of gold from the upper part of the man-made placer to the lower one, which indicates its redeposition during the filtration of dumps by surface waters.

Implementation of migration processes of gold-bearing inclusions in the near-flat part of the formation can be ensured by filtering the dump with surface and flushing waters, as well as due to surface stresses in the thickness of the layers of the dump during periodic freezing and thawing of the dump.

If there is a technogenic placer in the thickness of the rock dump, several types of deformation of the rock structure arise, which facilitate the migration of valuable components, sand and clay to the bottom of the dump and the formation of a sludge trap in it.

Such deformations include:

- suffusion, i.e. removal or movement of the smallest particles of rock mass by the filtration stream. In the presence of soluble salts in soils, additional chemical suffusion is possible;

- contact erosion, i.e. the destruction of cohesive rocks in contact with a larger material, due to the action of the filtration flow along the contact surface;

- peeling, i.e. separation by a filtration stream of particles and aggregates of clayey rocks with a fraction of galic and epic mass.

As a result of suffusion, there is an increase in the porosity of the rock with an increase in pore size, which creates the prerequisites for the migration processes of valuable components with a higher density. With contact erosion and peeling, the bonds between the upper and lower layers of the rock mass are weakened, which facilitates the forced displacement of the upper layers of the rocks to the lower.

The characteristics of the filtration flow are determined by many indicators, which in real conditions can vary widely. These factors include: the porosity and filtration capacity of the rock mass, the temperature of the water and rocks, the presence or absence of a water stop and its layout, the depth of freezing of the rock mass and the speed of its thawing.

The authors of the application conducted experimental studies of the separate effect of pressureless water flows and cycles of “freezing-thawing” on the formation of an enriched reservoir. The following data were obtained: when exposed to rock mass of non-pressure water flows, the speed of migration of gold particles in the horizontal plane is in the range from 0.95 to 1.6 mm / hour, in the vertical - 0.47 mm / hour; the migration rate of gold fractions as a result of “freeze-thaw” cycles is in the range from 1.6 to 0.3 mm / day (for gold particles with a size of 2.5 mm, for smaller fractions, the migration speed increases).

The fact of migration of zolotins under the influence of thawing and thawing cycles is not in doubt. The study of these processes involved Shilo, Shumilov. 1969: Vantsevich et al., 1969; Reshetnikov, 1970; Smeyan, 1977. The most detailed experimental and field studies of these processes were carried out by Yu.V. Shumilov et al. The fact of migration of gold grains is also confirmed by experiments carried out earlier at the Institute of Geology, Far East Branch, Russian Academy of Sciences.

The authors also established the migration of small gold fractions in the rock mass, consisting of fine sand and clay fractions during periodic freezing and thawing of the mountain gold mass, completely flooded with water. After a series of freeze-thaw cycles, processing the rock with layers 2 cm thick along the height of the experimental laying showed that a significant part of the gold fractions up to 0.25 mm in size migrated to the entire depth of the rock mass and reached the bottom of the experimental vessel.

However, the extraction of fine gold fractions, even previously concentrated in the lower layers of the blade, remains low, due to the complexity of the extraction process.

An increase in the degree of gold recovery can be carried out only after preliminary enlargement of gold finely dispersed inclusions, ensured by their adhesion as a result of contact and surface diffusion due to high pressure in the volume where they are located.

A known method of sorption fusion of gold particles, as well as gold and graphite with noble metals [see L.P. Plyuskina, T.V. Kuzmina, O.V. Avchenko Experimental modeling of gold sorption on a carbonaceous substance at 200-500 ° С, 1 kbar. Geochemistry 2004 No. 8, pp. 864-873.], In which the coalescence of small fractions was carried out at a pressure of 1 kbar and a temperature of 200-300 ° C, which then allows the extraction of gold particles from incoherent rocks by known technological processes. However, such a process of enlargement (particle fusion) is energy-intensive and is not applicable in real conditions while providing pressure in the dump volumes.

The proposed method of enlargement of gold-bearing fractions, based on the principle of increasing pressure, consists in deep freezing of the near-plank part of the blade, in which high pressures are achieved by eliminating deformation and expansion of the frozen layer.

The pressure developed during the freezing process is determined by the formula (see V. Novatsky "Dynamic problems of thermoelasticity", Moscow, Mir, 1970, p. 256):

where σ _kk is the pressure, P≈ (1.1-1.5) · 10 ⁷ Pa is the temporary resistance of ice under various conditions of its stress state at a negative temperature, K = 0.9 · 10 ¹⁰ Pa is the elastic modulus of ice, α _t = 0,053 · 10 ^-3 (1 / ° С) - coefficient of linear expansion of ice, θ - temperature, ° С.

The pressures developed during the ice formation process corresponding to various temperature parameters are given in Table 1.

Table 1 θ (° C) σ _kk (Pa) θ (° C) σ _kk (Pa) 0 1.310 ⁷ -10 2,73110 ⁷ -twenty 4,16210 ⁷ -thirty 5.59310 ⁷ -40 6.02410 ⁷ -fifty 8.45510 ⁷

The drawings show a pebble blade 1; ephelle blade 2; sludge trap 3; raftik 4, waterproof barrier 5, water intake platform 6 of the blade, vertical prefabricated end pipe collector 7, connecting pipes 8, control well 9, bottom air pipes 10, side air pipes 11, distribution air manifold 12, prefabricated air collector 13, pressure air pipes 14, exhaust pipes 15, a receiving vane type deflector 16, an exhaust deflector 17, air dampers 18 and 19.

The claimed method is implemented as follows.

The primary mining of an alluvial deposit is carried out in a known manner using known means, for example, using dredge, preferably up to a raft 4. In principle, cooling-heating means for a sludge tank (items 7-19) will not be necessary if mining is planned at very low winter temperatures ( below -40 ° C), but in other cases, cooling-heating means (items 7-19) can improve the efficiency of the process of sorption fusion of gold particles.

In the process of primary mining of the placer on the surface of the raft 4, a dump is formed, while at the beginning, within the area provided for dumping the dump, lashes of bottom air pipes 10, and also, if necessary, side air pipes 11 are placed (preferably parallel to each other). Then, on the site prepared in such a way, the dumping pad is dumped 2. When the scrap blade 2 reaches the specified area along its perimeter, a waterproof barrier 5 is created from a waterproof, for example, clay material (its height is determined is divided by the fraction of silt-epiline fraction in the placer material - the size of the ephel is less than 2 mm; the content of this fraction varies from 10 to 45% in the placer material), forming a sludge settler 3. Thus, the height of the barrier 5 from the raft 4 is from 0.1 to 0 , 4 from the height of the blade (the total height of the ephelle and pebble blade 1). When forming a waterproof barrier, it is advisable to additionally use a waterproof film material (not shown), for example high-pressure polyethylene.

Next, pebble blade 1 is poured onto the epoxy blade 2. Then, the top of the blade (formed by the material of the pebble blade 1) is profiled, creating a platform 6, preferably concave. This site 6 provides the creation of a filtration stream (top to bottom) in the body of the dump (water is supplied from a water source (not shown) by gravity, and also comes as rainwater. Then, at this site, control wells 9 are drilled and in a known manner cased with steel pipes.

During the filtration process, excess water is removed from the lower part of the ephemeral layer and from the sludge tank, flowing through the upper face of the waterproof barrier 5, and is removed from the dump. The waterproof wall 5 provides maximum water saturation of the blade in the sludge tank 3.

This device uses a two-stage freeze blade. First of all, with closed air dampers 18 and 19, the upper layers of the blade are frozen in height and perimeter (i.e., the volume of the blade is frozen, except for the volume of the sludge tank). The freezing front moves to the sludge trap 3, which will perceive the heat of phase transition when freezing moisture, providing an elevated temperature in it, in comparison with the upstream epic blade 2. When freezing the upper part of the blade, it is additionally moistened if the moisture content of the blade material is insufficient to freeze it.

The sludge tank 3 has thermal insulation in the form of bottom air pipes 10 connected by prefabricated air collectors 12,13, and side air pipes 11 connected by vertical collectors 7, connected by pipelines 8 to pressure 14 and exhaust 15 pipelines.

Freezing control of the bulk of the dump is carried out through control wells 9 with periodic sampling.

The second stage of freezing (freezing sludge tank 3) is carried out after deep freezing of the upstream part of the blade. At the same time, the shutter 18 is opened on the pressure air pipes 14, and the shutter 19 on the exhaust pipes 15.

At the entrance to the pressure air pipes 14, rotary receiving deflectors of the vane type 16 are installed, and at the ends of the exhaust pipes 15, exhaust deflectors 17 of a known design are mounted, which ensures the automatic placement of the receiving deflectors in the wind.

The pressure difference at the inlet 16 and outlet 17 deflectors provides a high-pressure head in the tube air system, and cold outside air enters the bottom air pipes 10 and side air pipes 11, freezing the sludge tank, which has the shape of a lens, bounded around the perimeter by a high moisture content epilayer layer. frozen in the first stage, and on top of the frozen mass of the ephemeral layer of the blade.

The wet rock of the sludge tank during freezing has limited expansion and deformation, due to the above reasons, which ensures the occurrence of high pressures and surface stresses in it.

The combined effect of pressure and cryogenic conditions will increase the dispersion of gold fractions due to surface diffusion of the metal during periodic cycles of freezing and thawing.

After several freezing-thawing cycles (preferably not less than ten to twenty), the dump is prepared for mining, casing pipes are removed from wells 9, cooling means and sludge settlers are removed (items 7-19), and then removed with a bulldozer (or dragline) top of the blade. Its lower boundary is detected by sampling from several control wells 9 before dismantling them. Further, in a known manner, using known technical means, for example, using a industrial device, the material localized in the volume of the sludge settler 5 is processed and the gold-containing component is recovered.

Claims (5)

1. The method of re-development of alluvial deposits, including dumping in the mined-out space of an epiline dump and subsequent dumping on its surface of a pebble dump using rock mass, extracted during mining of the whole placer, and subsequent excavation of the material of the dump with the extraction of gold particles, characterized in that before repeated mining of the dump carry out work on enlarging the size of the particles of gold, while before dumping the pebble dump in the near-flat part of the epic dump, the sludge is formed why, on the surface of the raft, a barrier is created from a waterproof, for example, clay, material covering the perimeter of the epic dump, while after dumping the pebble fraction onto the surface of the epic dump, the dump is kept for the time necessary to wash the volume of the dump with pressureless water flows, then freezing the blade, preferably using natural cold, preferably in two stages, starting with the volume of the blade except for the volume of the sludge tank, the freezing of which carry out last, in addition, when excavating the material of the blade, its volume located above the volume of the sludge tank is removed without washing. 2. The method according to claim 1, characterized in that before the excavation of the rock mass, freezing the blade is carried out repeatedly. 3. The method according to claim 1, characterized in that in the process of freezing the upper part of the blade, it is additionally moistened. 4. The method according to claim 1, characterized in that for washing the volume of the blade with pressureless water flows, natural water precipitation and / or forced supply of water to the surface of the blade are used. 5. The method according to claim 1, characterized in that when forming a waterproof barrier, a waterproof film material is additionally used.

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