RU2472105C1 - Method to outline mines and pillars in case of rock massif blasting - Google Patents

Abstract

FIELD: mining.

SUBSTANCE: method includes drilling of outlining and parallel compensation blast holes in a strictly determined order. The distance between outlining blast holes along the perimeter of the secured massif shall be equal to r_”р” (not higher than this value). The distance between outlining blast holes and the contour of the secured massif shall be equal to r_”СМ” (not higher than this value). The distance between outlining and compensation blast holes shall be equal to r (not higher than this value). Compensation blast holes are arranged at the side of the secured contour at the angle formed between the axis of outlining blast holes and axes of compensation blast holes equal to 60°. The values r_”р”, r_”СМ”, and r are determined depending on strength characteristics of the massif and capacity of the used explosive.

EFFECT: invention makes it possible to increase efficiency and safety of these types of works due to optimal distribution of wells or boreholes along a contour of a secured massif for specific mining-geological and mining-technical conditions.

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Description

The invention relates to the mining and mining and chemical industry and can be used to contour the massif during the construction of underground mine workings (underground tanks) and pillars during the explosive destruction of beaten rocks.

There is a known method of contouring mine workings when contour boreholes are drilled along the contour of mine workings under construction (B.N. Kutuzov, A.P. Andrievsky. New theory and new technologies for rock destruction by elongated explosive charges. - Novosibirsk: Nauka, 2002. - 39 -46 p.).

The disadvantages of the method are: violation of the explosion of the marginal space, the roughness of the created contour, the collapse of the marginal massif, a decrease in its strength characteristics and water permeability.

The closest in technical essence and the achieved result is a method of contour blasting (L.I. Baron, A.V. Klyuchnikov. Contour blasting during excavation of mine workings. - L .: Nauka, 1976. - 13 pp).

The disadvantages of the method are: a large amount of drilling work, the difficulty of forming dispersed charges, the lack of clear parameters for the location of the holes on the contour of a mine under construction and the formation of dispersed charges depending on the geological and mining conditions of blasting.

The aim of the invention is to increase the efficiency of drilling and blasting for specific mining and geological and mining technical conditions for mining, improving the quality of contouring of the rock mass, eliminating the possibility of disturbing the marginal space and increasing the stability of the marginal space, clearly defining the parameters of blasting for specific mining and geological and mining -technical conditions.

To this end, in a known method, including drilling contouring and compensation holes along the contour of the array to be beaten, placing explosive charges in the contouring holes and blasting them, drilling contouring holes is carried out in such a way that the distance between the holes must be equal to r _P (no more than this value) and the distance between the contour holes and the contour of the protected array at a distance r _СМ (no more than this value), compensation holes are drilled parallel to the contouring so that they should be located on The bottom of the crushing zone is an array (inside this circuit) at an angle of 60 ° towards the protected array.

The method is illustrated in the drawing, which shows the layout of contouring holes (3) and compensation holes (4) at an angle of 60 ° to the guarded circuit (1) on the contact zone of collapse - array (2).

The method is as follows. Contouring holes are drilled along the contour of the protected array in such a way that the distances between the holes are equal to r _P (no more than this value), and the distance between the contour and the drilled contouring holes is equal to r _СМ (no more than this value); at an angle of 60 ° in the direction of the protected massif, two compensation holes are drilled parallelly contouring in such a way that they are located at a distance r (inside this zone) at the contact of the crushing zone - the massif; make charging contouring holes their blasting (see figure 1).

The values of r _P , r _CM and r are defined as follows:

where d is the diameter of the holes, cm;

ρ is the density of explosives in a charged hole, kg / m ³ ;

D is the detonation velocity of the explosive used, m / s;

σ is the compressive strength of rocks, Pa;

τ is the ultimate tensile strength of the rocks, Pa;

To _With - the coefficient of structural attenuation, unit

The essence and example of a specific implementation of the method is as follows. The mining-geological and mining-technical conditions of mining operations are determined; Example 1: it is necessary to contour the massif in rocks with a compressive strength of rocks of 100 MPa; the ultimate tensile strength of the rocks is 30 MPa; monolithic array K _C = 1; hole diameter - 4 cm; loading density - 900 kg / m ³ ; BB ammonal (detonation velocity 4.5 km / s).

1) Determine the radius of the crushing zone formed during the explosion (according to formula 2)

r _CM = 0.35 × 4 × 900 ^0.5 × 4500 × 100000000 ^-0.5 = 18.9 cm ≈ 19 cm.

2) Determine the radius of the crack zone formed during the explosion (according to formula 1)

r _P = 0.21 × 4 × 900 ^0.75 × 4500 ^1.5 × (10 ⁸ ) ^-0.25 × (10 × 10 ⁷ ) ^-0.5 = 76.07 cm ≈ 76 cm.

3) Determine the radius at which the compensation holes are drilled (according to formula 3)

r = 19-4 = 15 cm.

Example 2: it is necessary to outline the massif in rocks with a compressive strength of rocks of 120 MPa; ultimate tensile strength of rocks - 40 MPa; monolithic massif K _C = 0.7; hole diameter - 5 cm; loading density - 1200 kg / m ³ ; Explosive granulite AS-8 (detonation velocity 4 km / s).

1) Determine the radius of the crushing zone formed during the explosion (according to formula 2)

r _CM = 0.35 × 5 × 1200 ^0.5 × 4000 × 120000000 ^-0.5 = 22.14 cm≈22 cm.

2) Determine the radius of the crack zone formed during the explosion (according to formula 1)

r _P = 0.21 × 5 × 1200 ^0.75 × 4000 ^1.5 × (120 ⁶ ) ^-0.25 × (4 × 10 ⁷ ) ^-0.5 × 0.7 = 57.27 cm ≈57 cm .

3) Determine the radius at which the compensation holes are drilled (according to formula 3)

r = 22-5 = 17 cm.

Having all the necessary data, we begin to drill contour and compensation holes, charge the contour holes and blast them with the condition that the distance between the contouring holes along the contour of the protected array is 76 cm in Example 1 (57 cm in Example 2), and the distance from the circuit equal to 19 cm in example 1, 22 cm in example 2 (before these holes); compensating holes are parallel contouring at a distance of 15 cm according to example 1, 17 cm according to example 2 (inside the contour the crushing zone is an array) at an angle of the collapsing explosion funnel 60 ° to the side.

Thus, the proposed method has the following advantages compared with the prototype: allows to exclude the possibility of violation of the marginal array; reduce the amount of drilling work; get the optimum number of holes (wells) along the contour of the protected array for specific mining and geological and mining conditions; get a clear outline of the protected array.

Claims (3)

1. The method of contouring mine workings and pillars during explosive blasting of the rock mass, including drilling contouring and parallel to them compensation boreholes along the contour of the massif, placing explosive charges in the contouring boreholes or bores and blasting them, characterized in that the distance between the contouring boreholes along the contour is determined from the expression:
r _p = 0.21 · d · ρ ^0.75 · D ^1.5 · σ ^-0.25 · τ ^-0.5 · K _C ,
where d is the diameter of the holes, cm;
ρ is the density of explosives in a charged hole, kg / m ³ ;
D is the detonation velocity of the explosive used, m / s;
σ is the compressive strength of rocks, Pa;
τ is the ultimate tensile strength of the rocks, Pa;
To _With - the coefficient of structural attenuation, unit 2. The method according to claim 1, characterized in that the contouring holes are drilled with a deviation from the protected circuit at a distance equal to the radius of the crushing zone, the size of which is determined from the expression:
r _CM = 0.21 · d · ρ ^0.5 · D · σ ^-0.5 . 3. The method according to claim 1, characterized in that two compensating holes are drilled parallel to the contouring holes at an angle of 60 ° formed between the axis of the contouring hole and the axes of the compensation holes, in the direction of the guarded circuit at a distance determined from the expression:
r = r _CM -d.