RU2699097C1 - Method for formation of technogenic deposit and its subsequent development - Google Patents

Abstract

FIELD: mining.

SUBSTANCE: invention relates to mining, in particular, to open-pit mining of minerals. For this purpose, in the base of the formed dump there created is a mine with a waterproofing layer, it is filled with mine mass prepared for leaching, which is also waterproofed and the dump is dumped over this mine working. To facilitate further development of technogenic deposit, wells with casing pipes installed in them are drilled from dump surface to supply working solution and further pumping of productive solution. Besides, for more reliable isolation of anthropogenic deposit from environment, accelerated reclamation of covering dump is performed.

EFFECT: creation of an industrial deposit together with formation of a mine dump of the maximum capacity and stability, and also increase of ecological safety of mine works and maximum extraction of a useful component at the subsequent leaching of the created technogenic deposit.

5 cl, 3 dwg

Description

The invention relates to mining, in particular to the development of minerals in an open way and can be used in the formation of a man-made deposit and its subsequent development.

The known "Method for the formation of a technogenic deposit", including the formation of an anti-filtration base, pouring an enriched layer of rock mass onto it, pouring a leachable layer out with two embankments, screening the side surfaces of the layer, treating the surface of the leachable layer, characterized in that a perforated pipeline is laid on the enriched layer, then laid antifiltration screen, on it the second layer of leachable rock mass (RU 2004804, application No. 05000602, from 01.07.1991, publ. 15.12.1993).

The disadvantage of this method is the need for laying a perforated pipeline and antifiltration screen, which can be damaged when laying a second layer of leached rock mass. In addition, the rocks used as a screen for the lateral surfaces of the dump can be eroded, and the dump itself is deformed due to uneven shrinkage of rocks of various types and particle sizes. (Reference. Open pit mining / K.N. Trubetskoy, M.G. Potapov, K.E. Vinitsky, N.N. Melnikov et al. - M.: Mining Bureau, 1994. p. 397, tab. 11.4. )

The well-known "Method of warehousing and storage of saline rocks in areas of permafrost." In this method, within a selected site, a layer of clay non-saline overburden (clay, loam, clay sands, marls, etc.) is deposited in a closed circuit, lying above the roof of the first brine horizon. The maximum filling height of a little filtering clay material is determined by the technological capabilities of transportation, as well as the stability parameters of the filled soil. Then, a layer of clay rocks is covered with stronger non-saline overburden, placing them mainly on the outside of the formed closed contour of the dump. The parameters of the formed closed antifiltration dump (perimeter and height) are determined by the need to have an internal free capacity sufficient to store the planned volume of saline rocks, and so that the final peak of salted rocks does not exceed the upper mark of the closed antifiltration dump from non-saline overburden. This will prevent the possibility of blowing salt-containing dust and spreading it around the surrounding area. (RU 2150581, application No. 98115861/03, dated 17.08.1998, publ. 10.06.2000 Bull. No. 16)

The disadvantages of this method are the presence of contact of the stored rocks with the environment, the low final capacity of the blade and the possibility of deformation of the blade due to the formation of water lenses in its base.

Also known is the “Method for the development of steeply dipping elongated deposits,” in which, in addition to placement of overburden, a man-made deposit is formed from substandard ores and enrichment waste in the open pit space, for which an antifiltration layer of sand and clay deposits and a protective layer of a fine rock fraction are laid, this is the formation of a technogenic deposit, protective and antifiltration layers, dumping of external and internal dumps, development of the next stage of a career Proportion conduct simultaneously, and after the formation of deposits in the space technogenic career proceed to its working out the leaching process, continuing the testing of the main deposit (application 95111264/03, 29.06.1995, opub. 27.06.1997.). This technical solution is considered by the author as a prototype.

This method of creating a technogenic deposit is simple to implement and reliable, since the sides of the quarry keep the stored rocks in a known place, their properties are preserved due to the exclusion of their erosion under the influence of weather factors and the presence of waterproofing.

However, if the development of the deposit is carried out in several areas at the same time, then, according to the above method, it is difficult to allocate a site for the formation of a technogenic deposit and for the disposal of a dump, in addition, the granulometric composition of substandard ores from different sites may differ and may not be optimal for their subsequent leaching .

The technical result of the invention is the creation of a man-made deposit in conjunction with the formation of a rock dump of maximum capacity and stability, as well as improving the environmental safety of mining and maximizing the extraction of a useful component during subsequent leaching of the created man-made deposit.

The technical result is achieved by removing the fertile layer within the boundaries of the projected technogenic deposit and storing it along the perimeter of mining operations, forming elongated embankments from potentially fertile rocks along its lateral edges, excavating the rocks to a predetermined level in the amount necessary for the formation of technogenic deposits, and the creation of them prevented in one of the ends of the educated production, the waterproofing of the educated production by filling and clay layer, laying a protective layer on it from a fine fraction of hard rock and dumping it on top of the formed technogenic deposit of the dump, coating it with a previously removed fertile layer and subsequent sodding of its surface, leaching the formed technogenic deposit is carried out by supplying a working solution through pipes from it surface and subsequent pumping out of the productive solution, as well as due to the fact that the bottom of the formed mine to accommodate the man-made field they give a bias from its edges towards its central axis, place a mobile crusher with a tape dumping agent on the preventer, and substandard ore intended for the formation of a technogenic deposit is crushed to the size optimal for its subsequent leaching using the above crusher and placed on top of the protective layer at the bottom of the tank in the form of cones, which, as the crusher with the spreader moves, are leveled to the upper edge of the waterproofing from compacted clay rocks on the side development, then waterproof the upper surface of the rocks loaded into the mine and fill the dump on top of the formed technogenic deposit, and fill in such a way that the edges of the lower part of the dump extend beyond the upper contours of the formed technogenic deposit and abut against mounds from potentially fertile rocks located along its lateral edges, and after the dumping is completed, its lateral slopes and embankments of potentially fertile rocks are flattened together.

In addition, drainage wells are arranged at the bottom of the mine intended for the placement of the technogenic deposit from the side opposite to the precalon.

Also, the formation of a technogenic deposit is carried out in stages as the generation for development is formed.

In this case, pipes for supplying the working solution and subsequent pumping out of the productive solution are installed in advance, and pipes for pumping the productive solution are placed along the central axis of the formed man-made deposit so that their lower end is in the lower part of the protective layer from a fine fraction of hard rock.

Moreover, the protective layer located under the technogenic deposit is formed from rocks of neutral composition, and the productive solution is pumped out with a delay of the time necessary for its filtration through the rock of the protective layer located under the developed technogenic deposit.

The invention is illustrated in the drawing, where in FIG. 1, FIG. 2 and FIG. 3 shows the implementation of the proposed method. So in FIG. 1 shows the stage of preparation for the development of a technogenic deposit, FIG. 2 shows its formation, and FIG. 3 shows sections of the formed field at different stages.

The method is as follows.

At the first stage, at the selected boundaries of the future technogenic deposit 1, a fertile soil layer is removed, which is stored with the possibility of further use at a certain distance from it. The fertile soil storage depot in FIG. 1, FIG. 2 and FIG. 3 is not shown. After that, the formation of elongated embankments from potentially fertile rocks 2 is carried out parallel to its borders 1. For their formation, rocks are used that are extracted from the excavation 3, intended for placement of the technogenic deposit, or brought from other places. Development 3 is placed within the boundaries of the formed technogenic deposit 1 so that it is located in their central part. Production volume 3 corresponds to the volume of substandard ore, which is planned for the formation of a technogenic deposit. The bottom of the mine 3 is inclined in the direction from its sides 4 to the central axis 5 located between its long sides. For the removal of the rock extracted from the mine 3 and the creation of Pre-6 at the end of the technogenic deposit being formed, car exits 7 are used. The same exits 7 are used to deliver clay rocks, from which a waterproofing layer 8 is formed by distributing them on the bottom and sides of the excavation 3 and their subsequent compaction, for example using bulldozers or road equipment. As the waterproofing layer 8 is created, a protective layer 9 is laid on it from a fine fraction of hard rock, while the protective layer 9 is poured so as to completely fill the lower part of the excavation 3, and its upper part is leveled to provide a horizontal surface 10, serving as the basis for the dumping of substandard ore, from which a man-made deposit is formed.

To drain the territory of the future man-made deposit and to prevent the formation of water lenses between the bottom of the mine 3 and the waterproofing layer 8 at its bottom, drainage wells 11 are arranged on the side opposite to the precut 6. Wells 11 can be built several times depending on the water cut of the base rocks and transferred as the foundation is constructed for filling the formed technogenic deposit. Water is discharged from the drainage wells 11 into a settling pond arranged near the boundary of the technogenic deposit 1, through temporary pipelines of which in FIG. 1, FIG. 2 and FIG. 3 are not shown.

After the area of the upper horizontal surface 10 of the base of the technogenic deposit becomes sufficient to accommodate substandard ores, a mobile crusher with a dumping agent 13 is placed on the upper working platform 12 of the preventer 6 and begin to fill the mine 3. The substandard ore coming from the quarry or from other places is crushed into mobile crusher 13 to the optimal size for subsequent leaching and is placed by means of a conveyor dump with it combined on the basis 10 in the form of cones 14. As the base 10 is filled with rock mass prepared for subsequent leaching 14, the cones 15 are leveled with a bulldozer, and if necessary to fill the remaining gaps, an additional amount of rock mass is poured. As the excavation 3 is filled on the surface loaded into it prepared for the subsequent leaching of the rock mass 14, waterproofing 16 is arranged. For this, it is possible to use both clay rocks and artificial polymeric materials.

After the area of the technogenic deposit being formed reaches the size that allows for car dumping from the side of the pre-entrance 6, dumping of the dump 17 begins. The dumping is carried out in blocks 18. In this case, the rocks are dumped from one side of mine 3 to the other perpendicular to the central axis 5. In the case of of necessity, for example, if there are large pieces of rock in the dump mass for a more uniform and gentle loading of the lower part of the blade in contact with waterproofing 16 use a mobile crusher with a dumping agent 13. Dumping of the dump is carried out until it reaches its design height and is completed when the contour of the upper boundary of the mine 3 is completely closed and the dump is in contact with embankments from potentially fertile rocks 2.

After the complete filling of one block 18 begin to fill in the next, and all operations are repeated in the same sequence.

After the formation of block 18 is completed, its surface is planned for subsequent remediation, before which wells are drilled from the upper dump site with casing installed in them. Wells differ in those intended for supplying working solution 19 and wells for pumping out productive solution 20. Wells 19 are drilled before they enter the bed with rock mass 14 prepared for subsequent leaching, and wells 20 are drilled into the lower part of the protective layer 9 from the fine solid rock fraction rocks, for which their depth is strictly controlled. Wells 20 are located in the central part of blocks 18 on axis 5, so that its end is as close as possible to the bottom point of the bottom of production 3, but does not extend beyond the protective layer 9. This location of the wells ensures complete extraction of the productive solution seeping through the protective layer 9 from neutral rocks and accumulating in the lower part of the mine 3. Wells 19 can be arranged in random order. Before the start of the exploitation of the technogenic deposit, the wellheads are isolated.

To prevent erosion of the blade and weathering, flattening of its slopes is carried out, and to facilitate subsequent reclamation, flattening of the blade 17 and embankments 2 is carried out jointly. To do this, using a bulldozer or excavator planner, the slope angle of the upper part of the blade 17 is aligned to the values of long-term stability for this type of rock and climatic conditions. After that, with the help of a bulldozer, potentially fertile rocks from embankments 2 are moved, starting from the bottom up, covering the less fertile rocks of dump 17 with a layer of potentially fertile rocks and forming a slope of the dump of a convex shape, thereby increasing its capacity, without compromising stability. After this operation is completed, the dump is reclaimed by distributing the fertile soil layer 21 from the temporary warehouse on its surface (not shown in Fig. 1, Fig. 2 and Fig. 3). This ensures the most rapid sodding of its surface and, consequently, the seepage of precipitation. As a result of these technological measures, the dump 17 acquires stability, which guarantees the minimum harmful impact on the ecology of the adjacent territory and the maximum safety of the technogenic deposit at its base.

From the foregoing it can be seen that the use of the proposed method allows to achieve the claimed technical result, and the signs characterizing the invention are necessary and sufficient for its implementation.

Claims (5)

1. A method of forming a man-made deposit and its subsequent development, including removing the fertile layer within the boundaries of the projected man-made deposit and storing it along the perimeter of mining, forming elongated embankments from potentially fertile rocks along its lateral edges, excavating the rocks to a predetermined mark in the amount necessary for the formation of man-made deposits and the creation of them prevented in one of the ends of the educated production, the production of waterproofing educated ejection by filling and subsequent compaction of a clay layer and laying on it a protective layer from a fine fraction of hard rock, dumping on top of the formed technogenic deposit of the dump, coating it with a previously removed fertile layer with subsequent sodding of its surface, leaching the formed technogenic deposit by supplying a working solution of pipes from its surface and subsequent pumping of the productive solution, characterized in that the bottom of the formed output to accommodate the technogenic deposits give a bias from its edges towards its central axis, place a mobile crusher with a tape dumping agent on the preventer, substandard ore intended for the formation of a technogenic deposit is crushed to the size optimal for its subsequent leaching using the above crusher and placed on top of the protective layer at the bottom of the tank in in the form of cones, which, as the crusher with the spreader moves, are leveled to the upper edge of the waterproofing from compacted clay rocks on its side on the working surfaces of the mine, after which the upper surface of the rocks loaded into the mine is waterproofed and the dump is dumped on top of the formed technogenic deposit, and the dump is made so that the edges of the lower part of the dump extend beyond the upper contours of the formed technogenic deposit and abut against mounds of potentially fertile rocks located along its lateral edges, and after the dumping is completed, its lateral slopes and embankments of potentially fertile rocks are flattened together. 2. The method according to p. 1, characterized in that at the bottom of the mine, designed to accommodate a man-made field, from the side opposite to the precaution arrange drainage wells. 3. The method according to p. 1, characterized in that the formation of the technogenic deposits is carried out in stages as the generation for development is placed. 4. The method according to p. 1, characterized in that the pipes for supplying the working solution and subsequent pumping of the productive solution are set in advance, and the pipes for pumping the productive solution are placed along the central axis of the formed technogenic deposit so that their lower end is at the lower parts of the protective layer of a fine fraction of hard rock. 5. The method according to p. 1, characterized in that the protective layer located under the technogenic deposit is formed from rocks of a neutral composition, and the productive solution is pumped out with a delay of the time required to filter it through the rock of the protective layer located under the developed technogenic deposit .

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