RU2265723C2 - Opened cast mining method - Google Patents

Abstract

FIELD: mining industry, particularly opened cast mining.

SUBSTANCE: method involves dividing and successively providing shifting of overlaying hill-shaped rock layers outside the cast by drilling well rings in shifting plane from drilling rooms, wherein the wells extend at an angle enough to initiate layer shifting during sliding surface preparation in rest prism area; placing charges into the wells and blasting thereof in rest prism area; supplying clay mix by its own gravity before sliding surface preparation in upper pressure prism part; blasting well rings in pressure prism area; opening the mine; excavating mineral and overburden rock; developing the cast up to design depth with cast wall building and creating dump of crashed overburden rock at cast contour.

EFFECT: increased efficiency of mineral excavation and reduced overburden ratio.

1 ex, 6 dwg

Description

The invention relates to the mining industry, to methods of open cast mining.

The method of open development of mineral deposits, including the separation and sequential organization of the displacement of the layers of the overlying strata of the hilly shape outside the quarry, is performed by drilling fan holes in the displacement plane from the workings at an angle sufficient to start the displacement of the layer when preparing the sliding surface in the area of the stop prism , charging and blasting fans of wells in the area of the prism stop, the subsequent introduction of gravity clay mud to the moment of creation of the sliding surface drilling in the upper part of the pressure prism and then blowing up the fans of the wells in the area of the pressure prism, opening the field, extracting minerals and overburden, mining the quarry to the design depth with the flanks detuning, and creating dumps of fragmented overburden rocks at the quarry contour. The method allows to increase the efficiency of the extraction of minerals while reducing the volume of stripping and a reasonable decrease in the ratios of stripping and the cost of developing mineral deposits.

There is a known method of developing mineral deposits, which consists in the fact that the mining and capital works are carried out at the field during the construction of the quarry in the form of capital and cut trenches, then overburden operations are carried out with the removal of waste rocks containing minerals, as a result of which access to field [Khokhryakov BC Open pit mining. M .: Subsoil. - 1974. - 264 p.].

The disadvantage of this method is the need to perform a large amount of stripping work before providing access to minerals. In addition, it is necessary to crush, destroy rock masses with a large specific consumption of explosives (up to 0.6-0.8 t / m ³ ), all this sharply increases the cost of overburden work in quarries and, therefore, the cost of mining.

The closest in technical essence and the achieved result is a method of forming artificial landslides during the development of upland deposits, which consists in the fact that the slope rock mass is proposed to be divided into inclined layers and further divided into large blocks and then transported along an inclined surface. Separation of blocks from the array is carried out sequentially by creating, under the base, as well as at the side and end surfaces of extended fluid fractures with a given orientation. To do this, on a given grid, drill central, additional, injection and control wells. In the bottomhole part of the central well, a disk-shaped initiating slot is cut with a special device in the fracture plane. In a special way, pressure is created in the injected fluid of this and other wells until the formation of cracks and a large-area fracture oriented in a given plane. Additives are gradually introduced into the fluid to increase its viscosity, for example, clay with a concentration of clay parts in suspension of 8-12% or more as a “lubricant” for transporting individual blocks in layers one after another along the slope [Chernov OI, Freidin A .M., Posokhov G.E., Uskov V.A. The formation of artificial landslides during the development of upland deposits // Mountain Journal. - 2003. - No. 9. - p. 15-17].

The disadvantage of this method is the increased amount of auxiliary work associated with drilling wells on a shallow grid, the creation in a special way of large breaking stresses in the interwell space and the difficulty of transporting individual blocks one after another on an inclined surface, and the efficiency of the method of producing overburden operations is determined by the influence of a large number of mining factors -geological and mining-technical nature.

The aim of the invention is to increase the efficiency of extraction of mineral reserves by reducing the volume of stripping, prepared in the quarry due to drilling and blasting operations, the use of expensive vehicles and a reasonable decrease in stripping ratios at the stages of field development.

This goal is achieved by the fact that in the method of open-pit mining of mineral deposits, including the separation and sequential organization of the displacement of the layers of the overlying strata of the hilly shape beyond the open pit boundaries, they are performed by drilling fan holes in the displacement plane from the workings at an angle sufficient to start displacement of the layer when preparation of the sliding surface in the area of the prism of emphasis, charging and blasting fans of wells in the region of the prism of emphasis, the subsequent introduction of clay mud by gravity ora by the time the sliding surface was created in the upper part of the pressure prism and then the fans were blown up in the area of the pressure prism, opening the field, excavating minerals and overburden, mining the quarry to the design depth with the flanks detuning and creating dumps of fragmented overburden near the quarry contour.

Increasing the efficiency of field development in hills by eliminating the labor-intensive processes of delivering equipment and machinery to the alpine zone for opening the field with ore passages and trunks and developing it from top to bottom by blasting rock rocks step by step (horizontally) using explosives with a specific consumption of 0.8-1 t / m ^3, loading rocks and its transportation by a distance of 3-5 km in outer blades is achieved by providing controlled artificial landslides given gravitational energy inclined layers into dormancy yvayuschey thicker hills (mountains).

Thus, overburden ratios can be significantly reduced in open pit mining.

Based on the analysis of the experience of creeping of the sides of quarries when creating excavations and cutting long inclined tectonic disturbances (cracks), we can conclude that there is a clear and reliable relationship between the angle of inclination of the sliding surface, the physicomechanical characteristics of the weakened layer of the underlying surface, and the nature of the displacement of the rock mass.

With "thick" lubrication like friction clay, in all cases a smooth displacement of the rocks along the sliding surface occurs. In this case, according to the experimental data, the angle of internal friction of the rock at the contact varies from 22-24 ° to 25-26 °. The adhesion of the rock in this case is 0.2-0.5 MPa. The angle of inclination of the sliding surface at lower values of rock characteristics is up to 30-35 °, and at higher values - up to 40-43 °. The last parameter of the angle of inclination of the shear surface is confirmed by the experience of the movement of rock layers on the side of the Kovdor complex ore pit at an angle of 43 °. In this case, the prevailing influence of the friction clay on the weakening of the massif was not revealed; it was ascertained that the reason for the creep of the rocks was the unsatisfactory parameters of the blasting parameters adopted during mining of the site.

It is advisable to transport the rock layer (landslide block) as a whole without crushing into parts, taking into account the existing forces in the prisms of pressure and emphasis. Given the movements of the layers in the slopes at angles of 35-36 ° and in the upper zones of 38-40 °, the sliding surface must be formed at an angle of 35-38 °. Smaller sliding angles are possible with small blocks with a relatively flat surface and a special type of lubricant with clay material.

When creating a displacement surface at horizons corresponding to the drilling height with one machine, workings are carried out, and drilling chambers are in them. Of these chambers, fans of wells 24–25 m long are drilled in the displacement plane, so the width of one strip is 48–50 m. With this step in mind, the intended sliding surface is drilled in the entire layer.

After blasting a portion of the sliding surface in the region of the stop prism, the introduction of clay mud from the production by gravity begins, and after completion of work, the wells of the upper portion of the sliding surface in the region of the pressure prism explode, as a result, the layer begins to smoothly shift along the inclined surface with a ratio of shear forces T _sd and resistance T close _sopr

T≥T comp _.

or in voltages:

τ _cd > τ _cn = k + tgφ · σ,

where τ _sd , τ _sp - respectively, shear stress and resistance; k - clutch; φ is the angle of internal friction; σ is the stress.

The effectiveness of the method is justified by the following calculation considerations. The extraction of rocks of volume V in the usual way will require costs 3:

C = C _in · V,

where C _in - the cost of excavation of 1 m ³ overburden when using blasting, excavation, transportation and laying of the rock in the dump.

When applying the method, the costs consist of carrying out horizontal workings along the height of the layer З _ext , cutting drill chambers З _бк , expenses for equipment and drilling delivery equipment З _т , drilling wells З _бс , blasting holes with explosives З _Sun , introducing clay _gr З З _gr .

The total costs will be

H _s = H _ext + H _bq + H _t + H _bs + H _sun + H _gr

With averaged estimates, the costs can be estimated taking into account the cost of work under the underground method of developing the field — when preparing blocks for a massive explosion by drilling and blowing up fans of wells and sinking preparatory workings.

By accepting the share of costs for mine workings, drilling and blasting of fan holes as 0.4 and 0.4 in the prime cost of 1 m ^{3 of} ore at the underground mine С _p , and the ratio of the prime cost of overburden excavation in open pits and ore in underground work as 1: 1.5, we can determine the cost of the implementation of the proposed method.

With a strip strip width of 50 m and a thickness of 60 m and a length of 250 m, the body volume will be V = 50 · 60 · 250 = 750,000 m ³ . The costs of its development in the traditional way З = 30 · 750,000 = 22500000 = 22.5 million rubles, where 30 is the cost of stripping 1 m ³ , rubles, and the costs of implementing method З ₂ = 2-2.5 million rubles. The economic effect per 1 m of the strike of the layer is 0.4 million rubles.

The drawings show a section of a field with a profile of the displaced layer along the sliding surface, a plan for the location of the workings and a graph of the change in the tangential stresses τ from the normal stress σ when the rocks move in the sides of the quarry and with clay material.

Figure 1. The section along the site of the field with the displacement of the layers along the sliding surface:

I, II - sequence of displacement of layers;

1 - sliding surface; 2 - drilling; 3 - plot of the sliding surface with clay material; 4 - ore body; l is the distance along the inclined plane between the workings; L _d , L _y - respectively, sections of the prisms of pressure and emphasis.

Figure 2. Scheme of the layer section along strike along the length L _1p with fans of wells:

In - the distance between the drilling workings along the strike of the layer.

Figure 3. The graph of the change in the tangential stress τ from the normal stress σ during the displacement of rocks in the sides of the quarry (1) and with clay material (2):

K _g , K _s , φ _g , φ _s - adhesion and angle of internal friction with clay material and without it.

Figure 4:

and - plot "Noisy-Cool" (Udokan);

b - Rasvumchorr plateau (apatite deposit - Khibiny);

c - Yuksporskoye field (Khibiny).

Concrete example

For a deposit of copper sandstones of Udokan, occurring under a hilly-like elevation of the overburden, based on a technical and economic analysis and calculation of their indicators, layer parameters and the angle of the sliding surface are determined. Similar calculations were performed for the deposits of the Central JSC Apatit mine in the area of cutting the gorge-shaped slope of an obliquely falling ore body and where the height of the steep slope is 200-250 m and its steepness is 55-80 °. Similar conditions for the application of the method are available at the Yuksporskoye apatite deposit, which is currently being developed by the underground method. Removing part of the overburden overburden by the proposed method would facilitate the effective use of the open method (Fig. 4 a, b, c).

In the given example, the thickness of the prepared layer for moving by gravity is 50-70 m, taking into account the topography, and on average - 60 m. The angle of inclination of the layer is 35 °.

The preparation of the layer for displacement is carried out in three stages.

At the first stage, at a certain height (30 m) along the layer height, workings of 2 × 3 m cross-section are carried out, in them drilling chambers are cut at a distance of 45-50 m from each other and drilling of fan holes begins along the plane of the layer displacement. For drilling wells, NKR-100 and Paramatic machines can be used. The diameter of the wells is 100-120 mm.

At the second stage, charging and blasting of fans of wells is carried out in the lower zone of the layer displacement section in the region of the prism of stop.

At the third stage, the introduction of the clay solution over the disclosure surface begins and, after completion of the work, the wells of the upper section of the layer displacement in the region of the pressure prism explode. A smooth displacement of the layer begins and after its completion, similar operations are repeated on the opposite section of the slope, which reduces the amount of overburden work and allows you to quickly discover the field and start working out it in a more progressive open way to the design depth with the detuning of the high sides and the creation of dumps beyond the quarry contour.

Sources of information

1. Khokhryakov B.C. Open pit mining. M .: Subsoil. - 1974. - 264 p.

2. Chernov O.I., Freidin A.M., Posokhov G.E., Uskov V.A. The formation of artificial landslides during the development of upland deposits // Mountain Journal. - 2003. - No. 9. - p.15-17 (prototype).

Claims (1)

A method of open development of mineral deposits, including the separation and sequential organization of the displacement of the layers of the overlying stratum of hilly shape beyond the boundaries of the quarry by drilling fan holes in the displacement plane from the workings at an angle sufficient to start the displacement of the layer when preparing the sliding surface in the area of the prism stop, charging and blasting fans of wells in the area of the prism stop, the subsequent introduction of gravity clay mud to the moment of creation of the sliding surface at the top part of the pressure prism and then blowing up the fan of the wells in the area of the pressure prism, opening the field, extracting minerals and overburden, mining the quarry to the design depth with the flanks detuning, and creating dumps of fragmented overburden rocks at the quarry contour.

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