RU2784839C1 - Method for carrying out explosive operations in the circuit zone of quarry - Google Patents

Abstract

FIELD: mining.

SUBSTANCE: invention relates to the field of blasting in mining and can be used in the explosive breaking of rocks with borehole charges of explosives in quarries when sloping the sides of quarries under conditions of restrictions on the seismic action of blast waves. The method for conducting blasting operations provides for placing a system of loosening charges and a system of linearly arranged in a row adjacent charges of contour blasting on the exploding near-contour block with instantaneous initiation of the latter and subsequent initiation of the system of loosening charges. In addition to the system of contiguous contour blasting charges arranged in a row, an additional row of contiguous contour blasting charges is placed in parallel to it from the side of loosening charges in a checkerboard pattern, simultaneously initiating both rows of contour blasting charges. The mass of each contour blasting charge in the additional row exceeds the mass of each charge of the system of contour blasting charges. The charges in the row of contour blasting are made in the form of garlands of cartridges, and the charges in the additional row are solid or with air gaps. The distance between rows of contour blasting charges exceeds the distance between charges in each row.

EFFECT: increasing the seismic protection of the sides of the quarry and protected objects during blasting in the periphery zones of quarries that develop strong and very strong rocks with minimal fissure voidness.

4 cl, 6 dwg

Description

The invention relates to the field of blasting in mining and can be used in the explosive breaking of rocks with borehole charges of explosives in quarries when sloping the sides of quarries under conditions of restrictions on the seismic action of blast waves.

With the existing technology of mining and blasting in quarries, protected objects are exposed to massive explosions. In order to reduce the seismic impact on protected objects, as a rule, a special technology is used in the contour zone of a quarry.

Reducing the intensity of seismic explosive waves is possible with the use of special designs of high explosives. Thus, there is a known method of conducting blasting in the near-contour zone of quarries, which provides for the placement of a system of loosening charges and a system of linearly arranged in a row adjacent charges of contour blasting on the blasted block, followed by instantaneous initiation of the last earlier initiation of the system of loosening charges (Melnikov N.V., Marchenko L. N. Explosion energy and charge design, Moscow, Nedra, 1964, p. 138).

To do this, borehole charges with air gaps are used. In this case, the peak pressure of stress waves decreases, and the duration of the impact on the blasted mass increases. This circumstance leads to an improvement in the quality of crushing of the rock mass by the energy of the explosion. This is important when conducting blasting operations in the near-contour zone of a quarry. allows to reduce the specific consumption of explosives and the mass of the charge in the well without deteriorating the quality of crushing rocks, but at the same time, the seismic and explosive impact on protected objects is also reduced. However, the creation of air gaps, especially in flooded wells, is non-technological, laborious and has a limited scope.

Due to these technological difficulties, in order to reduce the seismic impact on protected objects, in practice, as a rule, in the contour zone of a quarry, a special technology is used using a contour gap formed by an explosion of contiguous charges of explosives with a reduced mass of charges in wells located near the contour , using charges of a special design and methods of their initiation. Contiguous wells are drilled along the design contour of a quarry in the same plane parallel to each other and initiate instantly.

Thus, there is a known method of conducting blasting in the near-contour zone of quarries, which provides for the placement of a system of loosening charges and a system of linearly arranged in a row contiguous charges of contour blasting with the instantaneous initiation of the latter and subsequent initiation of the system of loosening charges (Graur. M.I. Process control destruction of rocks during contour blasting in order to obtain stable slopes of ledges in quarries.Thesis for the degree of candidate of technical sciences.Moscow, 1981, 201 pp.). The disadvantage of this method is the low efficiency of seismic safety in iron ore quarries with strong and very strong rocks.

This is due to the following reasons. The conducted studies have established that during the explosion of contour charges in rocks with a strength coefficient according to the M.M. Protodyakonov f=18-20, a wide fractured zone, as a rule, is not formed, but one main crack is formed with an opening not exceeding 10-15 mm. This is explained by the fact that the porosity of such rocks is practically absent, and the formation of a fractured zone is possible only when the rocks are compacted. At the same time, through such a “linear” contour gap formed by an explosion of charges with an annular air gap, seismic explosive waves pass practically without attenuation and reflection from it does not exceed 10-15%. At the same time, the degree of protection of the quarry wall and protected objects is at a low level.

It has been established that the formation of main cracks between the contour charges and their expansion under the action of gaseous detonation products of explosives occurs solely due to the dynamic compaction of the rock in the zone of such cracking. It should be noted that the methods for calculating the parameters of contour blasting are of the same type (Belin V.A., Ganopolsky M.I., Baron V.L. and others. Methods of conducting blasting. Special blasting. Textbook. Edited by prof. V. A. Belina, M., Iz-vo MGGU, 2007, 563 pp.) and do not give an answer to the size of the fractured zone and the width of the crack opening. And these parameters are directly related to the shielding effect of this zone. The specific consumption of high explosive in the contour zone of a quarry is determined, as a rule, from the fulfillment of the condition for a given degree of crushing of the rock mass and does not take into account the possibility of shielding such an explosive effect on the contour massif and the maximum safety of protected objects.

The conducted studies have shown that if the direction of natural cracks in the massif in the area of contour wells coincides with the line connecting the contour wells, then a crack or fractured zone is formed, the opening width of which depends on the strength characteristics of the blasted rocks. If natural fractures do not coincide with the front of contour wells, then only fracture growths are observed and a continuous gap may not form. As a rule, the propagation angles of natural fracturing and the contour series of wells do not coincide, which leads to “ragged” contours of the interwell space.

The mineral of iron ore quarries is strong and very strong rocks with minimal fissure voidness. Studies have shown that when using a typical layout of charges in the near-contour zone during the explosion of contour charges in iron ore quarries, a main crack of a small opening 8-12 mm or a “torn” surface of a fractured material with an opening not exceeding 22-30 mm is formed.

The technical problem to be solved by the present invention is to increase the seismic protection of the sides of the quarry and protected objects during blasting in the periphery zones of quarries that develop strong and very strong rocks with minimal fissure voidness.

The specified technical problem is solved by the fact that in the method of conducting blasting in the near-contour zone of quarries, which provides for the placement of a loosening charge system and a system of contour blasting charges linearly arranged in a row with the immediate initiation of the latter and subsequent initiation of a system of loosening charges, in addition to the system located in a row of contiguous contour blasting charges parallel to it from the side of the system of loosening charges in a checkerboard pattern, an additional row of contiguous contour blasting charges is placed, simultaneously initiating both rows of charges.

In the case when the degree of reflection and absorption of the “sawtooth” slot formed with such an arrangement of contour charges needs to be increased, then the mass of charges in the additional row is taken to exceed the mass of charges of the system of contour blasting charges, which leads to an increase in the width of the cracking zone and an increase in the protective function of the contour cracks. This technique can be performed by forming charges in a row of contour blasting in the form of garlands of cartridges, and charges in an additional row - solid or with air gaps.

To further increase the reflectivity of the "sawtooth" contour gap, the distance between the rows of contour blasting charges is taken to be greater than the distance between the charges in a row. This reduces the angle between the direction of propagation of seismic waves and the profile of the protective gap and the degree of reflection of the seismic impulse increases.

The essence of the proposed method is illustrated by the following images:

fig. 1 - layout of borehole loosening charges and contour wells of a "linear" type with garland charges of a cartridgeed explosive;

fig. 2 - diagram of the formation of a "sawtooth" type contour gap formed by garland-type contour charges;

fig. 3 is a diagram of the formation of a reinforced contour gap of the "sawtooth" type, formed by contour charges of a garland type and continuous contour charges of high explosive or charges with air gaps;

fig. 4 - diagram of the formation of a contour gap of increased reflectivity of the "sawtooth" type, formed by contiguous contour charges of a garland type;

fig. 5 - scheme of the exploded experimental unit in plan;

fig. 6 is a diagram of the placement of loosening borehole charges and contour holes of a "sawtooth" type with garland charges of a cartridgeed explosive.

The method is implemented as follows. When conducting mining and blasting operations, protected objects are exposed to massive explosions carried out using downhole loosening charges 1. Loosening charges are performed solid or with air gaps from placer or pouring explosives.

In order to reduce the seismic impact on protected objects in the contour zone of the quarry 2, technology is used using the contour slot 5, formed by the explosion of contiguous contour explosive charges 4 with a reduced mass of explosive charges in wells located near the contour, having a special (for example, garland) construction and previously initiated initiation of loosening charges (Fig. 1).

Contiguous wells 4 are drilled along the design contour of the open pit 2 in the same plane parallel to each other. Permissible deviations of the well axis from the contour plane are: 1% of the length of wells with a depth of up to 10 m and 1.5% of the length of wells exceeding 10 m. Permissible deviation of the distances between the mouths of contour wells in the contour plane from the design values is 1 well diameter from the design depth - 0.3 m.

The contour charge is a garland of explosive cartridges (for example, ammonite No. 6 ZhV with a diameter of d _n = 32 mm or ZKVK - a core contour blasting charge) tied to a detonating cord.

The linear density of the contour charge P _to is determined by the formula:

R _k \u003d K _m ×d _n , kg / m,

where K _m =32-36 - coefficient depending on the fracturing of the massif.

The distance between contour wells a _k is determined by the formula:

a _k \u003d K _nm ×a _m ×d _n , m,

where K _nm =1.0 - coefficient of geological conditions in the absence of a dominant system of fractures;

a _m =6.4-6.8 - typical relative distance between contour charges.

The length of the upper part of the contour well L _cv , free from charge, must be equal to the thickness of the upper layer of the massif disturbed by the explosion or weathering, but not less than 20 diameters of the contour wells. Wellheads should be closed with paper stoppers. According to the project, it is allowed to install plugs from stemming 0.5-1.0 m long in the upper part of the wells.

The mass of the loop charge in the well Q _k is calculated by the formula:

Q _k \u003d (LL _sv ) × p _k + Q _D , kg

where Q _D is the mass of the bottom charge, taken depending on the operating conditions of the contour charge in the range from 0.2 kg to 1.0 kg.

To protect the sides of the quarry 2 from damage, the distance a _k-m from a number of contour wells 4 to a number of technological loosening wells 1, closest to the contour wells 4, should be at least 9-10 diameters of loosening wells 1, depending on the strength and fracturing of the massif.

The zone of possible disturbance of the rock mass behind the contour gap m _K is determined by the formula:

m _K \u003d 1.3 × a _k-m × K _nk , m,

where K _nk =1 - correction factor, taking into account the direction of the main system of cracks in the array.

The shielding factor, which reflects the effectiveness of the contour gap 3, formed during the explosion under these conditions, is in the appropriate interval:

K_E=V/V_E=1.2-1.3,

where V_E is the rate (mass type) of changing the position of the array on the frontal part of the explosion wave (stresses) directly behind the slot itself, cm/sec.

To improve the seismic protection of protected objects in the method of conducting blasting in the near-contour zone of quarries, which provides for the placement of a system of loosening charges 1 and a system of linearly arranged in a row adjacent charges of contour blasting 4 on the exploding near-contour block with instantaneous initiation of the latter and subsequent initiation of a system of loosening charges 1, in addition to to the system located in a row of contiguous charges of contour blasting 4 parallel to it from the side of the system of loosening charges 1 in a checkerboard pattern, an additional row of contiguous charges of contour blasting 5 (Fig. 2-6) is placed, simultaneously initiating both rows of charges.

Thus, in the developed technology, it is proposed to form a contour gap 3 not by an explosion of linearly located charges 4, but to arrange them in two rows in a checkerboard pattern, which during the explosion leads to the formation of a contour gap 3 not of a linear or “torn”, but of a “sawtooth” shape. This shape of the contour slot provides additional reflection and interference of seismic and explosive waves and, as a result, an increase in the degree of seismic protection of protected objects and an additional improvement in the quality of rock mass crushing in the contour zone of quarry 2.

In the case when the degree of reflection and absorption of the "sawtooth" slot 3 (Fig. 2) must be increased, then the mass of charges in the additional row 6 (Fig. 3) is taken to exceed the mass of charges of the system of charges of contour blasting 4, which leads to an additional increase in the width of the zone crack formation 3 and increase the protective function of the contour gap. This technique can be performed by forming charges in a row of contour blasting 4 in the form of garlands of cartridges, and charges in an additional row 6 - solid or with air gaps from a placer or pouring explosive.

To further increase the reflectivity of the "sawtooth" contour gap 3, the distance between the rows of contour blasting charges 4, 5 is taken to be greater than the distance between the charges in a row (Fig. 4). This reduces the angle between the direction of propagation of seismic waves and the profile of the protective slot 3, whereby the degree of reflection of the seismic impulse increases.

To test the developed method of mining the contour zone of a quarry using blasting in strong low-fractured rocks, an experimental explosion was carried out, during the design of which the blasted block was divided into two parts - one of which had a “linear” scheme of contour wells, and in the other part of the block, protection of the contour wells space and protected objects was carried out by a "sawtooth" layout of contour wells (Fig. 5). To assess the effectiveness of the studied methods of mining the near-contour zone, at a distance of 300 m from the contour outside the danger zone of the explosion, measuring complexes of the seismic module 7 were placed. 6ZhV with an annular gap between them and the walls of the wells. Analysis of the records of seismic explosive waves by the measuring complex showed that in the zone of action of the contour charges of the "sawtooth" type, the amplitude of the mass displacement velocity is 4.0-4.5 times lower than in the zone of linear charges, which indicates the high efficiency of the proposed method.

Claims (4)

1. The method of conducting blasting in the near-contour zone of a quarry, which provides for the placement of a system of loosening charges and a system of linearly arranged in a row contiguous contour blasting charges with the instantaneous initiation of the latter and subsequent initiation of the system of loosening charges, characterized in that, in addition to the system located in a row of contiguous contour blasting charges parallel to it from the side of loosening charges in a checkerboard pattern place an additional row of contiguous contour blasting charges, simultaneously initiating both rows of contour blasting charges. 2. The method of conducting blasting according to claim 1, characterized in that the mass of each charge of contour blasting in the additional row exceeds the mass of each charge of the system of charges of contour blasting. 3. The method of conducting blasting according to claim 2, characterized in that the charges in the row of contour blasting are made in the form of garlands of cartridges, and the charges in the additional row are solid or with air gaps. 4. The method of conducting blasting according to claim 1 or 2, characterized in that the distance between the rows of contour blasting charges exceeds the distance between the charges in each row.

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