SU1196504A1 - Method of explosion-breaking of rock - Google Patents

Abstract

1. METHOD FOR EXPLOSIVE SEALING OF ROCKS, including penetration of a system of charging workings, partial filling; their explosive with the formation between the explosive and the destroyed mass of the free cavity, oriented in the direction of the destroyed mass, and initiating the explosion, which differs: so that, in order to increase the effect, -. 2 At the efficiency of the destruction of the array by ensuring simultaneous start of detonation of the explosive charge across its entire surface and enhancing the impact of the shock wave on the array while reducing the volume of tunnel works, the cross-section of the tube during the penetration gives the shape of the part of the circle facing the concave surface towards the array to be destroyed on which a layer of blister is placed, forming a charge that repeats in shape this concave surface, the free cavity between charge The jerky and destructible array is filled with explosive gas, and the initiation of explosive charge explosive is carried out by detonating the explosive gas excited from the geometric locus of points equidistant from the internal surface of the explosive charge in any cross section.

Description

2. The POP.1 method is distinguished by the fact that the charge development is given the shape of a spherical sector, and the detonation of the explosive gas is excited from the center of the sphere.

3. Method POP.1, characterized in that the charge generation is shaped into a cylindrical section of a torus, and the initiation of detonation of an explosive gas is carried out along the axis of the cylinder.

FIELD OF THE INVENTION The invention relates to the field of the mining industry, in particular to the carrying out of explosive

The aim of the invention is to increase the efficiency of destruction of an array by ensuring the simultaneous commencement of detonation of the explosive charge across its entire inner surface and the force of the blast wave acting on the array while reducing the volume of tunnel works.

FIG. Figure 1 shows a mine working diagram for blasting charges on horizontal cutting; in fig. 2 charge design when performing generation in the form of a spherical sector; in fig. 3 is a section A-A in FIG. 2; in fig. 4 is a mine working diagram for blasting charges for discharge; in fig. 5 - structural charge when performing the production in the form of a cylindrical sector; in fig. 6 is a section BB in FIG. five.

The method of blasting rock is carried out as follows.

On the border of the destroyed array 1 (Fig. 1), the charging outlets 2 are arranged to accommodate the charge of explosives 3 and the necessary connecting outlets 4. The cross-section of the charged openings 2 is shaped into a part of a circle with a center 5 facing a concave surface to the side of the destroyed array 1, on which the explosive charge 3 is placed, repeating in shape this concave surface.

On the opposite side of the massif, for example, horizontal cutting 6 is formed, forming a free surface, which contributes to an increase in the efficiency of crushing.

With a compact volume, the required disruption output 2 may be. passed in the form of a spherical sector (figure 2 and 3). With a large extent of the destroyed array, the mines 2 for accommodating the charge of explosives 3 may take the form of a cylindrical sector (Figures 5 and 6). Zar d BB 3 is placed on a curved surface of the generation 2 layer thicker than the critical thickness. The free cavity of generation 2 between charge of explosive 3 and the massif is filled with a blasted (for example, explosive) gas 7. 5

The initiation of an explosive charge explosion is produced by detonation of a charge gas 7, excited from the locus of points equidistant from 0 of the internal surface of the explosive charge 3. When the charge output forms in the form of a spherical Sector, the detonation of the explosive gas 7 is produced from the center of the 5 sphere (Fig. 2 and 3). In the form of charge, d5 Hort, in the form of a cylindrical sector of detonation of explosive gas, is produced along the axis 8 of the cylinder (Figs. 5 and 6).

The detonation of an explosive gas 7, which encloses the production space 2, is excited from the locus of points equidistant from the internal surface of the explosive charge 3, leads to the formation of a detonation wave concentrically diverging from the center 5. This wave reaches the curvilinear surface of generation 2 simultaneously around the entire perimeter and causes an explosion of a layer of chemical explosive 3 deposited on this curvilinear surface. Prma shock wave from vzresha layer chemically. BB 3 causes an abrupt amplification of the shock wave reflected from the walls of generation 2, which is generated by the detonation wave in the gas.

this amplification, the resultant reflected shock wave, converging to center 5 and amplifying in a cumulative manner, causes a secondary explosive impulse at center 5. Occurrence inside the mine to accommodate the charge

the effect of reverberation (multiple reflection) of shock waves leads to an increase in the total time of impact of the impulses on the destroyed array, which contributes to the quality of the destruction of the array.

 5 fpui.Z А-А

Fig.Z

FIG L

6-5

Fig 6

Claims (3)

: 1. METHOD FOR EXPLOSIVE BURNING OF ROCKS, including the driving of a system of charging workings, their partial filling with explosive with the formation of a free cavity between the explosive and the destructible array, oriented towards the destructible array, and the initiation of the explosion, distinguishing, with, that the purpose of increasing the efficiency of destruction of the array by ensuring the simultaneous onset of detonation of the explosive charge over its entire inner surface and enhancing the effect of the shock wave on the array at the same time mennom reduction in the volume of tunnel works, the cross-section of developments in the sinking. they give the shape of the part of the circle facing the concave surface towards the destructible array, on which the explosive layer is placed, forming a charge that repeats the shape of this concave surface, the free cavity between the explosive charge and the destructible array is filled with explosive gas, and the explosion of the explosive charge is initiated detonation of explosive gas excited from a geometrical place of points equidistant from the inner surface of the explosive charge in any cross section , Workings. 2. The method according to claim 1, characterized in that the charge generation is shaped spherical, sector, and the detonation of explosive gas is excited from the center of the sphere. 3. The method according to claim 1, characterized in that the charge generation is shaped into a cylindrical sector, and the detonation of explosive gas is excited along the axis of the cylinder