RU2734651C1 - Method of multi-row short-delayed blasting - Google Patents

Abstract

FIELD: mining.

SUBSTANCE: invention relates to mining, to the field of drilling and blasting works in rocks and can be used in various industries, which use multi-row short-delayed blasting (SDB) in massifs of rocks, in particular during explosive preparation of rock mass to excavation in open development of minerals and construction materials. Proposed method comprises drilling of parallel rows of wells, their charging with explosive followed by stemming, erection of blasting network and its initiation. Surface and borehole decelerators for installation of explosive network are selected by condition of minimum number of charges exploding in intervals of 20 ms and minimum coefficient of variation of mass of explosives in these groups at full time interval of explosion action.

EFFECT: technical result of claimed method is reduction of seismic effect of mass explosion of well charges with provision of required degree of crushing of rock mass before excavation due to rational combination of denominations in set of surface and well retarders.

1 cl, 1 tbl, 1 dwg

Description

The invention relates to mining, to the field of drilling and blasting operations in rocks and can be used in various industries using multi-row short-delayed blasting (KZV) in rock massifs, in particular in the explosive preparation of a rock mass for excavation in the open development of minerals and building materials ...

The known method of short-delayed blasting with a central location of the main row of detonation of surface devices of a non-electric initiation system. To control the explosion, shock-wave tubes with pyrotechnic retarders are used. The blasting network is mounted in the form of a "herringbone" from the "trunk" passing through the central row of wells, and "branches" extending from it to the right and left. Each well of the central row is initiated sequentially one after the other after 42 ms. With a lag of 25 ms, wells are initiated in pairs, located in rows to the right and left of the central row. Thus, according to the authors, no more than two wells are simultaneously initiated, located in the same row to the right and left of the central row. To ensure the elimination of the well bottomhole, downhole decelerations with a nominal value of up to 500 ms are installed. (Rubtsov S.K., Ershov V.P., Bibik I.P., Kustikov T.P. Features of the use of non-electric systems of initiation at the Muruntau quarry. Mining information and analytical bulletin "Explosive business" - M .: World of the mining book " , 2007. - S. 342-345). The installation of surface decelerations that control the sequence of initiation of borehole charges by a combination of decelerations of 25 and 42 ms, according to the authors, makes it possible to form a collapse convenient for excavating the rock mass and reduces the peak load on the rock mass by detonation products and thereby reduces the seismic and shock-air impact on the nearby objects.

The disadvantage of this method is that in multi-row blasting, pyrotechnic borehole detonators with a nominal value of 500 ms, in which the response time spread is up to 9%, leads to the fact that at the indicated nominal surface retarders, significantly more than 2 borehole charges will explode in the interval 20 ms, and therefore the seismic effect of the explosion will increase.

The known method of short-time blasting of rocks with emulsion and granular explosives using non-electric initiation systems (patent of the Republic of Kazakhstan KZ (13) A4 (11) 25144 (51) F42D 1/00 (2010.01) F42D 3/04, published on 15.12.2011, bull. No. 12) in which an explosive network is mounted in the form of a "herringbone" from the "trunk" passing through the central row of wells, and the "branches" extending from it so that the rocks of any fortress are blown up using decelerations, the intervals of which in the "trunk" and in "Branches" are determined by the formulas:

t _st = 108-5ƒ; _vet t = 70-3ƒ,

where: t _st is the deceleration interval in the "trunk" of the explosive network, ms; t _vet - deceleration interval in the "branches", ms; ƒ - rock hardness on the scale of prof. M.M. Protodyakonov.

The disadvantage of this method is that its main purpose is only the quality of crushing the massif, without taking into account the seismic impact. With the combination of the retarders 65 and 42 ms, as indicated in the invention, it is possible to detonate adjacent charges with an interval of about 20 ms. At the same time, the authors do not take into account the spread of the response time of not only surface retarders, but also downhole retarders, which give a much larger error in the order of explosions of downhole charges.

The method of short-delayed blasting in rocks of any fortress should create conditions for rational crushing of the massif with a minimum seismic impact on the protected objects. Theoretically, this condition is achieved by choosing such a combination of surface and downhole retarder ratings that would provide the minimum number of charges that explode in an interval of 20 ms. (In accordance with clause 843 of the Federal norms and rules in the field of industrial safety "Safety rules for blasting operations" it is considered that the explosion of several explosive charges in the interval of 20 ms is considered as a charge detonated simultaneously, with an increase in the seismic effect).

The technical result of the proposed method is to reduce the seismic impact of a massive explosion of borehole charges while ensuring the required degree of crushing of the rock mass before excavation due to a rational combination of ratings in the set of surface and borehole retarders.

The specified technical result is achieved by the fact that in the method of multi-row short-delayed blasting, including the determination of the parameters of drilling and blasting operations, the choice of explosives and initiation means (SI), drilling parallel rows of wells, loading them with an explosive with subsequent stemming, assembling an explosive network and short-delayed blasting, according to According to the invention, a set of SI, which includes surface and borehole retarders for mounting an explosive network, is carried out on the basis of calculating the n _max and V _m criteria for various combinations of deceleration ratings. As criteria when comparing the options, the maximum possible number of charges in a group that fall during the explosion in the interval of 20 ms (n _max, pcs) and the coefficient of variation of the mass of explosives in these groups (V _m ,%), which determines the relative spread of the random variable and shows , what proportion of the average value of this value is its average spread.

This criterion is used on the basis that there is an approximate empirical estimate of the event in statistics. If the variation index V _m ≤33%, then the statistical population is considered homogeneous.

In the case we are considering, this means that the total mass of the explosive will be evenly distributed over the groups throughout the explosion.

Different ratios of surface and borehole slowdowns lead to different distribution of the total mass of borehole charges over the intervals of simultaneity. The unevenness of their distribution entails an uneven distribution of local peaks of displacement velocities, which is unfavorable from the point of view of the seismic effect of a mass explosion. Obviously, with the same borehole depth and, accordingly, the same charge mass in the boreholes, the coefficient of variation of the mass will be equal to the coefficient of variation of the number of charges in the groups.

The most favorable from the point of view of the seismic impact of an explosion is the case of a uniform distribution of the total mass of explosives in groups. Such a situation is only possible with highly accurate, fully electronic initiation, where each borehole charge can be programmed with an appropriate blast time. The use of pyrotechnic slowdowns in the surface network and, moreover, inside the wells predetermines the random nature of the formation of groups. Therefore, the coefficient of variation of such a random variable as the mass of the charge in the group will be V _m > 0. The greater the coefficient of variation, the greater the intensity of the seismic impact of the explosion.

The choice of a set of surface decelerations with a rational combination of denominations that provide a rational degree of crushing of the massif is carried out by calculation according to the known dependence of the deceleration time between adjacent charges in transverse (daughter) rows (Mosinets, V.N. Crushing and seismic action of an explosion in rocks. - M. : Nedra, 1976 .-- 271 p.)

where W is the line of least resistance m; C is the velocity of the longitudinal wave in the rock mass, m / s.

Based on the calculation of τ ₂ , the retarder is selected the closest at par from the number of products manufactured by the industry.

FIG. 1 shows a diagram of the installation of a surface network at short circuit, in which W is taken as the distance between successively exploded charges in transverse (daughter) rows.

As an example, we will select retarders for the installation of an explosive network when preparing rock with a strength coefficient according to prof. M.M. Protodyakonov ƒ = 9, with a grid of wells a = 6.5 m; b = 6.5 m; W = 6.5 m.

The longitudinal wave velocity in the rock mass is 1800 m / s.

Using the formula (1), we determine τ ₂ = 72 ms. Choose from the parametric series TU Iskra-P τ ₂ = 67 ms.

The response time of the applied retarders obeys the normal distribution law with known parameters: τ ₁ , τ ₂ , τ ₃ - respectively, the nominal decelerations between the wells of the main longitudinal row, between the wells in the daughter transverse rows and downhole deceleration, ms; σ ₁ , σ ₂ , σ ₃ - the corresponding standard deviations, ms. Let s ₁ , s ₂ , s ₃ denote the corresponding random deviations from the denominations, ms.

, где

в зависимости от положения заряда в схеме соединения могут принимать значения τ₁, s₁ или τ₂, s₂. Поэтому случайное время срабатывания заряда будет определяться рекуррентной формулойThe response time t _{i of} the i-th charge in each separate sequence will be the sum of the response time of the previous charge of the given sequence t _i-1 , the random time of deviation of the downhole moderator s ₃ from its nominal value and the random response time of the surface moderator

where

depending on the position of the charge in the connection scheme, they can take on the values τ ₁ , s ₁ or τ ₂ , s ₂ . Therefore, the random response time of the charge will be determined by the recurrent formula

In this entry, the index i corresponds to the position of the considered borehole charge relative to the previous earlier retarders along the path of the initialization pulse in accordance with the surface mounting scheme of the explosive network.

In the general case, any scheme for connecting charges can be associated with a rectangular table, in the cells of which the random response time of the detonator cap of each individual charge will be presented.

The results of calculating the comparative indicators of the Iskra-T and Iskra-S devices at various combinations of surface decelerations are presented in Table 1, in which cells are highlighted (darkened), which correspond to the predominant combination of surface decelerations when comparing the considered types of downhole blasting caps.

In Table 1, the corresponding values of the coefficient of variation are highlighted in bold italics, which show that when using downhole devices with electronic retardation, the possibility of ensuring the uniformity of the explosion of charges is much greater than when using pyrotechnic devices. For all combinations, with the exception of τ ₁ = 350, τ ₂ = 176, the Iskra-T device has an advantage over the Iskra-S device both in the number of charges in the maximum group and in the uniformity of distribution of the total mass of explosives in groups. ... The noted exception is associated with an almost exact two-fold ratio of surface denominations.

From a comparison of the combination of options in Table 1, it can be seen that when using Iskra-P surface moderators in the transverse (daughter) rows (τ ₂ = 67 ms), in the main row it is most preferable to use τ ₁ = 350 ms or 176 ms, where V _m has minimum values. Then, with the Iskra-T downhole moderator (τ ₃ = 1000 or 2000 ms), during the entire explosion time, from 1 to 4 charges can simultaneously explode, and when using the Iskra-S downhole moderator with the same combination of deceleration ratings in the surface network during During the entire explosion, from 3 to 7 charges can simultaneously explode, i.e. almost twice as large and the seismic effect of the explosion will be stronger.

Thus, the use of borehole blasting caps with electronic retardation practically for all combinations of surface pyrotechnic retardation device ratings provide a reduction in the maximum number of simultaneously exploded charges in a group and a more uniform distribution of groups in time. The obtained estimate of the maximum number of charges in a group and the coefficient of variation of the mass of explosives in the groups makes it possible to recommend the choice of a combination of borehole and surface decelerations during blasting operations, as a result of which a decrease in the seismic effect of a mass explosion can be expected.

An example of a specific implementation of the method.

Blasting at the Kedrovsky section of the rock mass, divided into two parts, was carried out in the mountain area No. 1, horizon 79-84 at the bottom of block 147 in the bottom of the excavator P&H-2800 # 152. For the experiment, a typical block of rock mass was used, including sandstone with a strength of ƒ = 9 on the scale of M.M. Protodyakonov. Blockiness category IV. Wells with a diameter of 216 mm were drilled with D-50KS No. 77, 91 drilling rigs. The depth of the wells ranged from 13 to 26 m. The well pattern was square with a distance between wells of 6.5 m and a distance between rows of wells of 6.5 m. The number of longitudinal rows of wells ranged from 4 to 7. The estimated amount of RPGI-100 explosives was 208309 kg. The specific consumption of explosives averaged 0.833 kg / m ³ , which in TNT equivalent is 0.667 kg / m ³ . Wells with a depth of 13 to 18 m, a total of 157 pcs. were charged with solid charges, and dispersed charges were formed in 196 wells with a depth of 18 to 26 m.

The block was conditionally divided into experimental control parts, on which the circuit for initiating the explosive network was mounted using various Iskra slowing devices.

In the control section of the block, the depth of the wells was variable and ranged from 13 to 21 m. The installation of the network was carried out according to the calculations of OOO KRU Vzryvprom and the technology used in the section. Surface moderators "Iskra-P-200" in the main line, "Iskra-P-109" in transverse rows and downhole moderators "Iskra-S-2000" in each part of the borehole charge were used.

In the experimental section of the block, the depth of the wells was 20-21 m. When installing the network, it was recommended to use surface moderators "Iskra-P-176" in the main line, "Iskra-P-67" in transverse rows and in each part of the borehole charge, borehole detonators with electronic deceleration "Iskra-T-2000".

The explosion was recorded with a high-speed Casio Exilim Pro EX-Fl video camera with a video recording speed of 600 frames per second. Slow viewing of the video made it possible to establish the direction and nature of the camber movement.

During the explosion at a distance of 900 m, seismic sensors were installed to record the speed of the earth's surface

When evaluating the results of observations and measurements of the seismic effect of the explosion, it was found that in the control part of the block in some places the charges exploded ahead of the main part of the explosion. This testifies to the scatter of the triggering moments of the Iskra-S-2000 retarders. The rate of vibration of the earth's surface at a distance of 900 m from the explosion was 14.8 mm / s from the control part of the explosion, and 13.1 mm / s on the experimental part, which is 11.5% less and in accordance with the claimed technical solution indicates a more uniform the distribution of the mass of explosives and a smaller number of charges, exploding in a 20 ms interval.

Claims (1)

A method of multi-row short-delay blasting, including drilling parallel rows of boreholes, loading them with an explosive with subsequent stemming, installation of an explosive network and its initiation, characterized in that surface and borehole retarders for mounting an explosive network are selected according to the minimum number of charges exploding at intervals of 20 ms, and the minimum coefficient of variation of the explosive mass in these groups over the entire duration of the explosion.

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