RU2256873C1 - Method for drilling blasting of rocks - Google Patents

Abstract

FIELD: mining industry, applicable at blasting of rocks on the ground surface, at blasting of ores in the underground conditions and driving of underground open pit minings.

SUBSTANCE: the method for drilling blasting of rocks includes drilling of boreholes with subsequent their loading with explosive charges, short-delay blasting and registration of seismic oscillations on one block. Then, the zone with the maximum quantity of simultaneously blasted deep-hole charges on this block is determined according to the amplitude of speed exceeding the preset level on the seismograph. After that the intervals of operation between the adjacent charges on the next block are increased with due account made for the obtained results of measurements on the previous block.

EFFECT: provided the necessary degree of rock crushing at an allowable level of seismic action on the environment.

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Description

The invention relates to the mining industry, and in particular to methods of drilling and blasting breaking rocks, and can be used for breaking rocks on the earth's surface, for breaking ore in underground conditions, as well as for underground mining.

A known method of drilling and blasting breaking rocks, including drilling wells, followed by charging them with explosive charges and a short-blown blasting of borehole charges [1].

The disadvantage of this method is the possibility of premature blasting of borehole charges, which causes a deterioration in rock crushing, an increase in seismic impact on the environment and the collapse of the slopes of the open pit mines.

A known method of drilling and blasting breaking rocks, including drilling wells with their subsequent charging with explosive charges, short-blown blasting, using a contour series of charges and recording seismic vibrations [2]. This method is adopted as a prototype.

In this method, when the permissible level of seismic impact on the rock mass is exceeded, the mass of charges in the groups is reduced, which leads to a deterioration in the quality of rock crushing. In addition, this method also has the disadvantages indicated above in the analogue.

The objective of the invention is to provide the necessary degree of crushing of the rock at an acceptable (calculated) level of seismic impact on the environment and the safety of the slopes of the ledges.

This is achieved by the fact that in the method of drilling and blasting rock blasting, including drilling wells with their subsequent charging with explosive charges, short-blown blasting and registration of seismic vibrations, determine the zone with the maximum number of simultaneously exploded borehole charges on one block by the maximum excess of the magnitude of the amplitude of the velocity of seismic vibrations over by its set value on the seismogram, then the response time intervals between adjacent charges on the next block are increased the time intervals - in the previous unit area with a maximum amplitude of the velocity of seismic vibrations exceeding a predetermined level, with the subsequent adjustment of intervals deceleration triggering other unit charges with increasing intervals deceleration pickup charges in subsequent blocks continue to provide a predetermined level of seismic influence on the rock massif.

Figure 1 shows the location of the wells on the ledge.

Figure 2 shows a diagram of an explosive network.

Figures 3 and 4 show seismograms of explosions on two quarry blocks.

The quarry is mined by blocks 1, on each of which several rows of vertical wells 2 are drilled, followed by their charging with explosive charges 3, installation of an explosive network 4 with downhole and surface retardants 5, 6, commutation of explosive charges in each row and short-blown explosive charges using a detonator 7 In this case, the occurring oscillations are recorded by means of a seismic recorder 8 installed at a predetermined distance R from the block (see Fig. 1). In the process of blasting borehole charges in some cases, quasi-simultaneous blasting occurs, i.e. several charges fall in their decelerations into the time tolerance of the spread interval for downhole moderators. In this case, a stochastic picture of the phenomenon is observed with different tolerances of the deceleration intervals for each well, and the total seismic effect of the impact can be estimated only by analyzing the explosion seismogram on the block. On the seismogram, zones with simultaneously exploded charges are determined by the excess of the amplitudes of the oscillation velocities over their predetermined value, at which the energy of the blast wave provides the necessary degree of crushing of the rock while maintaining the stability of the escarpment of the ledges and the seismic impact on the environment within acceptable limits. The level of such energy is determined by a known method [3]. Next, choose the zone with the maximum number of simultaneously exploded borehole charges for the maximum excess of the magnitude of the amplitude of the velocity of seismic vibrations over a given level. In this zone, a blast wave is formed with maximum energy, leading to the collapse of the escarpment of the ledges and negative impact on the environment. Blast waves with velocity amplitudes exceeding a given level can also lead to collapse of slopes. The number of simultaneously exploded explosive charges in this zone is determined by the countdown method according to the seismicity coefficient, the distance from block 1 to the recorder 8, the maximum value of the amplitude of the speed of seismic vibrations, which calculate the maximum mass of simultaneously exploded charges, and the mass of one charge. To ensure a given level of seismic impact on the rock on the next block, the response time intervals between adjacent charges are increased relative to the time intervals in the zone of the previous block with the maximum explosive energy corresponding to the maximum amplitude of the speed of seismic vibrations exceeding the specified level, with subsequent adjustment of the intervals of deceleration of the remaining charges block. The increase in the response interval of nearby borehole charges is proportional to the number of simultaneously exploded explosive charges in the zone with maximum explosive energy and should be greater than the total maximum allowable deviation of the response times of two adjacent charges. This increase in the time interval is established empirically for specific mining and geological conditions. In the event of simultaneous explosions of charges on subsequent blocks with a seismic effect exceeding a predetermined level, the intervals for slowing down explosions continue to increase similarly to ensure a given level of seismic effect on a rock mass and the environment.

An example implementation of the method.

At the Vostochny quarry of the Olympiadinsky GOK, CJSC Polyus, explosive crushing of a block is carried out by borehole explosive charges located in ten rows of two groups in a row with two charges in the group and two single explosive charges with a distance between rows of a = 6.5 m and the distance between the borehole charges b = 6.5 m. The rocks are quartz-micaceous-carbonate with a coefficient of strength according to M.M. Protodyakonov ƒ = 10 ... 12.

As explosives, grammonite 79/21 is used. The blasting is carried out according to a wedge pattern using a non-electric blast initiation system (SINV). Blasting is carried out by simultaneous actuation of charges in the group with a deceleration interval of 42 ms between group explosions in the same row and a deceleration interval of 67 ms between borehole explosions in adjacent rows (see the diagram of the explosion of borehole charges in Fig. 2). The maximum deviation of the operation intervals of the surface inhibitor of the SINV-P type from the nominal value is ± 9.2 ms according to the passport data and of the downhole moderator of the SINV-S type ± 24 ms. When explosive charges are blown, seismic vibrations are recorded according to the indicated scheme by means of a Delta-GEON-02 type seismic signal recorder. According to the amplitudes of the velocities of seismic vibrations exceeding a given level of seismic impact on rocks, zones with simultaneously exploded charges are determined. In this case, the specified level of seismic impact on the rocks corresponds to the value of the amplitude of the velocity of oscillations from the simultaneous explosion of two borehole charges, which is determined by the seismogram and it is V = 5.2 cm / s (see figure 3).

Next, determine the number of simultaneously exploded charges in the zone with a maximum amplitude V _{max of} seismic vibrations. The magnitude of the amplitude of the speed of seismic vibrations from the explosion of two charges V ₁ = 5.2 cm / s, the mass of two charges Q ₁ = 500 kg, the distance R = 170 m from the blast unit to the recorder for these mining and geological conditions determine the seismicity coefficient by the formula

, которая вызвала сейсмические колебания с максимальной амплитудой скорости, вычисляемой также по сейсмограмме по трем осям (см. фиг.3) и равнойThen determine the total mass Q _max explosive charges equal to

, which caused seismic vibrations with a maximum amplitude of velocity, also calculated from the seismogram along three axes (see figure 3) and equal to

.and correspondingly

.

Knowing the mass of one charge Q ₁ equal to 250 kg, determine the number of simultaneously exploded charges n in the zone with the maximum amplitude of the velocity of seismic vibrations

At the same time, only 2 charges were blown up in time (with a given deceleration), and the remaining 16 charges were blown up quasi-simultaneously, which exceeded the estimated number of charges in the group by 8 times. On the next block, the response time interval between adjacent borehole charges is increased to 109 ms, and the interval between the retardation of explosions between the rows was saved and equal to 67 ms. After the explosion of explosive charges of this block, the maximum value of the amplitude of the oscillation velocity at a distance of 200 m was 1.1 cm / s. From the seismogram of this explosion it follows that the magnitude of the amplitude of the oscillation velocity does not exceed its predetermined level with the simultaneous explosion of two borehole charges (see figure 4). As a result of drilling and blasting operations using this method, the degree of crushing of the blasted rock mass is ensured in accordance with current standards and the seismic impact on the environment is minimized.

Sources of information

1. Kutuzov B.N. Destruction of rocks by explosion (explosive technologies in industry). - M.: Publishing. Moscow State University, 1994, p. 154-159.

2. Kutuzov B.N. Rock destruction by explosion. - M.: Publishing. MGGU, 1992, p. 404-410 (prototype).

3. Mosinets V.N. The crushing and seismic effect of an explosion in rocks. - M .: Nedra, 1976, p. 228.

Claims (1)

A method of drilling and blasting rock blasting, including drilling wells with their subsequent loading with explosive charges, short-blown blasting and registration of seismic vibrations, characterized in that they determine the zone with the maximum number of simultaneously exploded borehole charges on one block by the maximum excess of the magnitude of the amplitude of the speed of seismic vibrations over its specified value on the seismogram, then the response time intervals between adjacent charges on the next block are increased relative to time intervals - in the zone of the previous block with the maximum amplitude of the speed of seismic vibrations exceeding a predetermined level, with subsequent adjustment of the intervals for slowing down the operation of the remaining charges of the block, and the increase in the intervals of slowing down the response of charges on subsequent blocks continues to ensure a given level of seismic impact on the rock mass.

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