RU2278972C1 - Method for steep ore deposit development - Google Patents

Abstract

FIELD: mining, particularly underground ore deposit development.

SUBSTANCE: method involves dividing ore deposit into mining levels, cutting the mining levels in descending order and filling excavated space with hardening filling material, wherein filling material is supplied from day surface via main filling holes drilled in ledge wall rock outside shifting zone, which is formed in ledge wall rock during full ore deposit development. The first layer is cut from one mining level boundary along ore deposit strike in direction to another mining level boundary. Additional filling holes are drilled in zone defined by two lines before the first mining level cutting. The first line is extension of resulting excavated space boundary from ledge wall side. The second line is extension of the first mining level boundary along ore deposit strike, from which mining level is cut. Main filling holes are drilled before putting additional filling hole out of operation. If additional filling holes are arranged within the shifting zone forming in ledge wall rock during full ore deposit cutting additional holes are operated up to cleaning work development stage. At cleaning work development stage additional well deformation is equal to threshold deformation values. Safe additional hole operation is impossible if deformations exceed above threshold values. In particular case additional filling holes are made along bisector of angle defined by two lines, namely by the first line, which is extension of resulting excavated space boundary from ledge wall side, and by the second line, which is extension of the first mining level boundary along ore deposit strike, from which mining level is cut.

EFFECT: reduced mine construction time.

2 cl, 2 dwg, 1 ex

Description

The invention relates to mining and can be used in underground mining of mineral deposits.

Known methods for developing steeply falling ore deposits, including dividing the ore deposit into floors, sequential mining of reserves within the ore deposit in a descending order, filling up the developed space resulting from the extraction of minerals, by hardening filling material, feeding filling material from the surface through filling wells (B book: V.I. Khomyakov, Foreign experience of laying in mines, M., Nedra, 1984, p.165-177).

The disadvantages of these known methods are significant amounts of mining operations when opening an ore deposit and the high complexity of the processes associated with the transportation of filling material.

A known method (adopted as a prototype), including sequential mining of floors (horizons) in a descending order, the full filling of the worked out space with hardening filling material, the supply of filling material from the surface through major filling wells drilled in rocks outside the area of dangerous displacements of the rock mass associated with mining ore deposits. (In the book: Imenitov VR, Underground mining processes during underground mining of ore deposits. Moscow, Nedra, 1984, p. 454-447).

The disadvantages of this known method in the reverse order of mining floors are significant amounts of mining operations when opening the ore deposits and the high complexity of the processes associated with the transportation of filling material.

These drawbacks are related to the fact that when using the known method (prototype), by the time the mine is put into operation with the reverse order of floor mining, it is necessary to go through long wells with large lengths and field drifts approximately equal to half the floor size along strike.

Capital wells are located outside the zone of movement of the rocks lying side. The boundaries of this region are limited to planes drawn to a horizontal plane at angles of complete displacements β ₁ , the values of which for most ore deposits are in the range of 50-60 degrees.

Angles of displacement are angles external to the mined space, formed on vertical sections along the strike and across the strike of the ore deposit (at the sites of greatest displacements) by horizontal lines and lines connecting the boundaries of the mined space with the boundaries of dangerous displacements at the bedrock contact with sediments.

As follows from practical experience, the length of cross-bars designed for transporting filling material from a filling well to drifts of ventilation-filling horizons when developing deposits with dip angles of 50-80 ° at depths of 400-600 m is 350-400 m or more.

The technical result achieved by using the proposed method is to eliminate the disadvantages of the known prototype method, namely, reducing the volume of mining operations when opening the ore deposit and the complexity of the processes associated with the transportation of filling material from the wells to the place of its laying.

The technical result is achieved by the fact that the inventive method of developing steeply falling ore deposits includes dividing the ore deposit into floors, working out the floors in descending order, filling the worked out space with hardening filling material, supplying filling material from the surface through major filling wells drilled in the rocks of the lying side outside the zone the displacement formed in the rocks of the lying side of the ore deposit at its full (ore deposit) mining (or, which is the same, by the time it is completed) tions of its mining).

According to the invention, the development of the first floor begins from one of the boundaries of the first floor along the strike of the ore deposit and leads towards the other boundary of the first floor along the strike of the ore deposit, before the start of mining the first floor, auxiliary filling wells are drilled, capital filling wells are drilled until auxiliary filling wells, while auxiliary filling wells are drilled within the area bounded by lines, one of which is a continuation the boundary of the mined-out space from the side of the lying side, and the second - the continuation of the boundary of the first floor along the strike of the ore deposit, from which the mining of the floor begins, and with the location of auxiliary filling wells within the zone of displacement formed in the rocks of the lying side when the ore is fully mined, operation auxiliary wells continue to the stage of development of treatment works, in which the values of deformations of auxiliary wells become equal to the ultimate deformations, in excess of which support safe operation of wells is not possible.

To increase the effectiveness of the proposed method, auxiliary filling wells are placed on the bisector of the angle formed by the lines, one of which is an extension of the developed space border from the lying side, and the second is a continuation of the boundary of the first floor along the strike of the ore deposit, from which the development of the floor begins.

The essence of the proposed method is illustrated by the diagrams presented in figure 1 and figure 2.

Figure 1 shows a schematic diagram of the placement of capital wells relative to the boundaries of the zone of dangerous displacements of the rock mass in the lying side of the ore deposit, formed at the time of completion of mining of the ore deposit.

Figure 2 shows a schematic diagram (plan view) of the placement of auxiliary and capital wells relative to the boundaries of the ore body.

In figures 1 and 2:

FQCD - the worked-out part of the first floor;

ABQF - part of the first floor to be worked out;

SD - the boundary of the first floor along the strike of the ore deposit, from which the development of the first floor begins;

AB - the boundary of the first floor along the strike of the ore deposit, towards which the mining of the first floor is conducted,

HELL - the boundary of the first floor from the lying side;

BC - the boundary of the first floor from the side of the hanging side;

FD - the boundary of the worked out space from the lying side of the ore deposit;

S is the size of the floor along the strike of the ore deposit;

1 - ore deposit;

2 - capital wells;

3 - cross-cut, passed between the capital wells and ventilation filling drift;

4 - ventilation and filling drift;

5 - the boundary of the zone of displacements of the rock mass, formed at the time of completion of mining ore deposits;

6 - auxiliary wells.

DP is the bisector of the ODM angle formed by the lines DM and DO, one of which (DM) is a continuation of the boundary of the mined-out space FD from the lying side, and the second (DO) is a continuation of the floor boundary (CD) along the strike of the ore deposit, from which floor mining begins ;

β ₁ - the angle of displacement in the rocks of the lying side with the full development of the ore deposit;

β ₂ - the angle of displacements in the rocks of the hanging side with the full development of the ore deposit;

and - the distance between the lying and hanging sides of the ore deposit in the horizontal plane (horizontal thickness of the ore body).

α is the angle of incidence of the ore deposit;

b ₁ - the distance from the ore deposit to the boundary of the zone of displacements of the rock mass, formed from the side of the lying side by the time the mining of the ore deposit is completed;

b ₂ - the distance from auxiliary filling wells to the ore deposits;

h ₁ - the inclined height of the first floor;

h ₂ - the inclined height of the second floor.

The method is as follows. Ore deposit 1 (figure 1) is divided into floors. The mining of floors is done in a descending order. Mining of the first floor begins from one of the boundaries of the first floor along the strike of the ore deposit and leads towards the other boundary of the first floor along the strike of the ore deposit. Prior to the start of mining of the first floor, auxiliary filling wells 6 are drilled within the ODM area bounded by lines, one of which is an extension of the FD of the worked out space from the lying side, and the second is an extension of the CD of the first floor along the strike of the ore deposit, from which the mining of the floor begins.

Auxiliary wells 6 are used in the initial period of mining the ore deposits. By the time the auxiliary filling wells are shut down, capital filling wells 2 are being drilled.

When auxiliary filling wells are located within the displacement zone, which is formed in the rocks of the lying side by the time the ore deposit is completed, the operation of auxiliary wells continues until the stage of development of treatment works, at which the deformation values of auxiliary wells become equal to ultimate deformations, beyond which safe operation of auxiliary wells impossible.

To achieve the maximum efficiency of the proposed method, auxiliary filling wells are placed on the bisector of the ODM angle formed by lines, one of which is an extension of the developed space boundary from the lying side, and the second is an extension of the first floor boundary along the ore deposit strike, from which the floor development begins.

The boundary of the displacement zone 5 (figure 2), which is formed in the rocks of the lying side, is determined at the time of completion of mining of the ore deposit.

Justification of the materiality of the distinguishing features.

"... mining of the first floor begins from one of the boundaries of the first floor along the strike of the ore deposit and leads towards the other boundary of the first floor along the strike of the ore deposit ..." and "... before the start of mining of the first floor, auxiliary drilling wells are drilled. .. ".

The development of the floor from one of the boundaries (SD) of the first floor along the strike of the ore deposit towards the other (AB) boundary of the first floor along strike along with the drilling of auxiliary wells 6 within the area limited by the lines of OD and OM (Fig. 2) allows minimize the amount of work associated with the excavation of mine workings (cross-bars, drifts of the ventilation and filling horizon) necessary for transporting filling material from filling wells to the laying site, by the time the mine is put into operation (beginning of mining the first- floor).

When using the known method (prototype), by the time the mine is put into operation, it is necessary to pass stowage-ventilation drifts 4 with a length approximately equal to half the size of the floor along strike (S), and stowage crosshitch (crosshairs) 3 with a length of at least ₁ between the ventilation-stowage drift 4 and capital filling wells 2.

When applying the proposed method pass only the cross-section 7 (figure 2), the length of which ( ₂ ) is several times less than the length of the cross-section 3.

The drilling of auxiliary wells 6 within the area bounded by the DO and DM lines is characterized by minimal tensile and shear stresses in the bedrock rock mass. Increased compressive stresses in the considered area of the lying side array, presented during the development of ore deposits, as a rule, with solid rocks, do not have a significant negative effect on the state of the wells. This circumstance allows us to significantly reduce the distance between auxiliary wells and ore deposits and significantly reduce the cost of maintaining technologically satisfactory condition of the wells. The most stable state of auxiliary wells is ensured when they are located on the DP line, the bisector of the ODM angle, where tensile and shear stresses have minimum values.

"... when the auxiliary filling wells are located within the displacement zone, which is formed in the rocks of the lying side by the time the ore deposit is mined, the operation of auxiliary wells continues until the stage of development of development work, at which the strain values of auxiliary wells become equal to the ultimate deformations, exceeding which safe operation of auxiliary wells is not possible ... "This feature is a condition under which the use of auxiliary wells is possible Vazhiny, and consequently conditions under which the proposed method can be realized.

The field of rational use of the proposed method.

The inventive method is intended mainly for use in underground mining of powerful ore deposits with dip angles of more than 35-40 degrees.

Compared with known methods, the inventive method allows you to: several times reduce the volume of mining operations when opening the ore deposits associated with the implementation of filling crossbreeds and filling drifts; reduce the complexity of the processes associated with the transportation of filling material to the place of laying. In addition, when using this method, the construction time of the mine is significantly reduced.

The parameters necessary for the implementation of the proposed method, namely the ultimate deformation of auxiliary wells, beyond which safe operation of these wells is impossible, is determined as a result of mine, laboratory or analytical studies, taking into account specific mining and geological conditions for mining the ore body.

The location of the boundary of the displacement zone 5 (figure 2), which is formed in the rocks of the lying side by the time the mining of the ore deposit is completed, is determined before the drilling of auxiliary wells.

1) At the angles of displacement β ₁ and β ₂ (Fig. 1) of the rock mass, established at the time of completion of mining of the ore deposit. The values of the angles of displacement β ₁ and β ₂ can be obtained using known methods, for example: Emelyansky BC, Poliy V.D., Sakaeva T.Sh. Prediction of the movement of the earth's surface during the development of steeply falling bodies with a hardening tab. Mining Journal, 1986, No. 5, pp. 51-54; Kuznetsov M.A., Akimov A.G., Kuzmin V.I. and others. Rock displacements in ore deposits. M., Nedra, 1971; Akimov A.G. Determination of the angles of displacement for deposits of complex shape and limited size. "Mountain Journal", 1963, No. 12; Akimov A.G. The dependence of the angles of displacement on the degree of undermining of the earth's surface. Proceedings ATTENTION, Sat LII, ed. ATTENTIONS, L., 1964.

2) As a result of the analysis of the results of instrumental observations of the movement of rock masses during field development under conditions similar to those considered.

3) As a result of modeling underground mining of ore deposits on models of equivalent materials (Kuznetsov GN, Budko MN and others. - Studying the manifestations of rock pressure on models. Ugletekhizdat, 1959).

An example of a specific use of the proposed method for mining Yakovlevskaya iron ore deposits in the conditions of the Yakovlevsky mine.

The Yakovlevskaya deposit with a thickness of 250-300 m lies at a depth of 600-800 m from the surface. The angle of incidence of the ore deposit is 55-65 °. The size of the ore deposit along the strike is 1400-1500 m.

The ore deposit in the conditions of the Yakovlevsky mine (Fig. 1) by fall is divided into two floors. The vertical height (h ₁ , h ₂ ) of each of the floors is 60-65 m. The floors are worked out in a descending order, the first is worked out above the floor with a vertical height h ₁ . The worked out space is filled with hardening filling material. The development system within the floors is layered with ore excavation within the layers by fillings. Layers work out sequentially, starting with the top layer.

The location of the boundary of the displacement zone 5 (Fig. 2), which is formed by the time the second floor is completed, is determined as a result of modeling on models of equivalent materials.

The minimum distance from point D to the border of the displacement zone 5 (figure 2), which is formed in the rocks of the lying side by the time the mining of the second floor is completed, is 100-110 m.

The development of the first floor (Fig. 2) starts from the right boundary of the floor (SD) along the strike of the ore deposit and leads towards the left border (AB) of the floor along the strike of the ore deposit. Before the start of mining of the first floor, two (one reserve) auxiliary filling wells 6 are drilled.

Auxiliary filling wells 6 are placed on the DP OD bisector of the ODM angle (Fig. 2) within the displacement zone formed in the rocks of the lying side when the Yakovlevsky ore deposit is fully mined, i.e. at the time of completion of the second floor mining.

The distance from point D to the location of the auxiliary wells 6 is about 70 m.

The operation of auxiliary wells 6 (Fig. 2) is continued until the stage of development of treatment works, in which the strain values of auxiliary wells become equal to the ultimate deformations, beyond which the safe operation of auxiliary wells is impossible. Actual values of deformation of auxiliary wells are determined during their operation by instrumental observations.

Prior to the cessation of operation of auxiliary wells 6, capital filling wells 2 are drilled. Capital filling wells 2 are located outside the boundary 5 (Fig. 2) of the displacement zone formed in the rocks of the lying side at the time of completion of mining of the ore deposit, i.e. by the time completion of the second floor.

The values of the angle of displacement β ₁ (figure 1) in the conditions of the Yakovlevsky mine are about 55 °. The minimum allowable length of capital filling cross-ditches, determined from the conditions for the location of wells outside the area of dangerous rock displacements in the lying side of the ore deposit, is more than 400 m.

Using the proposed method in the conditions under consideration allows you to: reduce by more than 4 times the total length of the filling crosshairs and 7 times the length of the ventilation and filling drifts; reduce the construction time of the mine by at least 7-8 months; 20-30% or more to reduce the complexity of the work associated with the transportation of filling material in the initial period of the mine.

According to preliminary estimates, the service life of auxiliary wells 6 (the initial period of the mine) will be at least 3-5 years.

Claims (2)

1. A method for developing steeply falling ore deposits, including dividing the ore deposit into floors, working out the floors in descending order, filling the worked out space with hardening filling material, supplying filling material from the surface through major filling wells drilled in the rocks of the lying side outside the displacement zone, which is formed in the rocks of the lying side with the full development of the ore deposit, characterized in that the development of the first floor begins from one of the boundaries of the floor along the strike of the ore hall and lead towards the other floor boundary along the ore deposit strike, before the start of mining the first floor, auxiliary filling wells are drilled, capital filling wells are drilled until the completion of auxiliary filling wells, while auxiliary filling wells are drilled within the area limited by lines, one of which is a continuation of the border of the worked-out space from the side of the lying side, and the second is a continuation of the boundary of the first floor the development of the ore deposit, from which the floor begins to be mined, moreover, when the auxiliary filling wells are located within the displacement zone formed in the rocks of the lying side when the ore deposit is fully developed, the operation of auxiliary wells continues until the stage of development of development work, at which the deformation values of auxiliary wells become equal ultimate deformations beyond which safe operation of auxiliary wells is impossible. 2. The method according to claim 1, characterized in that the auxiliary filling wells are placed on the bisector of the angle formed by the lines, one of which is a continuation of the boundary of the worked space from the lying side, and the second is a continuation of the boundary of the first floor along the strike of the ore deposit, from which start working out the floor.

Images