RU2275587C1 - Method for determination of optimal parameters of explosive destruction of rocks - Google Patents

Abstract

FIELD: drilling and blasting operations in hard rocks with the use of a multicharge short-delayed blast, applicable in various branches using blasting operations in rock masses.

SUBSTANCE: the method includes measurement of the value of the specific power intensity of rock drilling in the process of drilling of blast holes and calculation according to it of the parameters of the explosive charges, plans and intervals of delay at blasting of them, estimation of the results of the blast by the power intensity of excavation of the rock mass and selection of the optimal parameters of the blast according to the statistics data. According to the invention, several blasts are performed on rock samples with similar properties of the mass with fixation of the precise time of initiation of each explosive charge, and a model of actual development of the mass explosion in real time and space for the particular blasting plan and construction of charges is constructed. At achievement of rational results of the blast, i.e. the mass properties, the parameters of the charges and sequence of their initiation in time and space are considered as optimal parameters of explosive destruction for masses with similar indices and accumulated in the data bank. The claimed method makes it possible to study the mechanism of development of the blast of explosive charges in the regime of real time directly in the rock mass and not on models.

EFFECT: determined the precise pattern and mechanism of development of the mass blast in real rock mass.

3 cl

Description

The invention relates to the field of blasting in strong rocks using multi-row short-blast blasting (MKZV) and can be used in various industries that use blasting in rock massifs of rocks.

It is known that the delay time interval for the MKSV should be selected on the basis of two conditions: the explosion of the first series of charges should ensure the destruction of the explosion funnel, and the explosion of the second series should occur before the ejection prism begins to separate from the array, because otherwise, the stress field from the second charge does not penetrate the ejection prism [1]. Due to the fact that the determination of the deceleration time in production conditions is fraught with considerable difficulties due to the large spread in the intervals of successively operating moderators (30-80% of the nominal value) and no one can give an accurate picture of the development of an explosion of a group of charges in time and space in the array rocks (it becomes probabilistic in nature), the deceleration intervals are either calculated analytically or taken according to simulation data, for example, by blasting on glass models. In both cases, errors are large, because the fact that the stress field arising in the rock mass, developing in all directions from the charge, encounters cracks, bedding surfaces and outcrops that are almost impossible to take into account either in the calculations or in models - they are different for different types of rocks and the conditions of their occurrence in specific massifs.

The closest to the essence of the problem being solved is a method for a comprehensive full-scale study of the energy parameters of explosive rock destruction based on the assessment of the rock mass resistance to blasting by specific energy intensity of cone drilling and the quality of rock crushing by specific energy intensity of rock excavation. When drilling blast holes, the energy intensity of the drilling is measured, the values of the specific energy intensity of the drilling are used to calculate the specific consumption of explosives for blasting rocks of this type. After the explosion, the specific energy consumption for the excavation of 1 m ^{3 of} rock mass is determined, which allows you to simultaneously take into account both the quality of crushing of the rock mass and such indicators as the coefficient of loosening, rock density, height of collapse [2]. A set of statistical material on blasting and mining blocks with the same characteristics of the rock mass sets the optimal parameters of explosive charges, circuits, and deceleration intervals during their explosions, corresponding to a minimum of energy consumption for excavation.

The disadvantage of this method, adopted as a prototype of the claimed invention, is the need to collect a large amount of statistical material because of the “black box” principle incorporated in it: only the input properties of the system “rock mass - explosive charge - rock mass” are measured (rock mass, charge parameters) and output - the energy intensity of excavation. The sequence of operation of the specific system “rock mass - explosive charge” is unknown due to the probabilistic nature of the explosion of a group of charges in time and space due to a 30-80% deviation from the nominal value of the response time of series-connected moderators, for example, pyrotechnic relays during detonating explosions cord.

The technical problem to which the invention is directed is to establish an accurate picture and mechanism for the development of a mass explosion in a real rock mass.

The problem is achieved in that in a method for determining the optimal parameters of explosive destruction of rocks, including measuring the specific energy consumption of drilling rocks during drilling of blast holes and calculating explosive charge parameters, patterns and deceleration intervals during their blasting, evaluating the results of an explosion with a mining excavation energy intensity mass and the choice of optimal parameters of the explosion according to statistics, according to the invention, several explosions are carried out with experimental fixes with the same array properties By specifying the exact time of initiation of each explosive charge, they build a model of the actual development of a mass explosion in real time and space for a specific explosive scheme and charge design.

When rational explosion results are achieved, the combination of specific indicators of the properties of the array, the parameters of the charges and the sequence of their initiation in time and space are considered the optimal parameters of explosive destruction for arrays with similar properties and accumulate them in the data bank.

Work blocks are divided into sections with the same properties of the array and for each of them the optimal parameters of explosive destruction from the accumulated data bank are selected.

The method for determining the optimal parameters of explosive destruction of rocks is carried out, for example, using a mobile installation-shelter described in [3], as follows. Blast holes are drilled with energy measurement for drilling to calculate explosive charge parameters, patterns and deceleration intervals between explosions of individual borehole charges or their groups. The mobile installation-shelter is adjusted to the area of the ledge ready for explosion, and the slope and the surface of the ledge are covered with vertical and horizontal frames. Then the blast network is mounted by connecting the fibers of each blast hole with the switching element of the laser charge initiation system located in the back of the shelter.

The control element of the laser charge initiation system sends an executive command to the laser to issue an initiating pulse, which through the fiber enters the explosion initiator located in the well. After the signal from the photocell about the supply of a light pulse to the given fiber arrives at the control element, the control element fixes this moment of time in the microcomputer memory as the initial one and starts from it the countdown of the deceleration time for the next explosive charge, into which the next pulse should arrive according to the design explosive design. After the deceleration interval specified by the design scheme has elapsed, the initiation cycle is repeated.

Blasting under a mobile shelter allows you to record the moment of laser initiation of a specific charge and accumulate this information in the memory of a microcomputer at a laser station in the back of a shelter or transmit it by radio directly to a computer in a dispatch service. Shelter of an explosive massif eliminates the spread of rock mass and protects the measuring equipment.

After the explosion of the explosive charge group, the shelter is moved to another section of the block. In the blown up area, mass explosion indicators are estimated for the energy intensity of excavation. With rational explosion indicators, the combination of the properties of the array determined before the explosion with the parameters of the actual development of the mass explosion (the mass of the explosive charge, the exact time of initiation of each charge and its spatial location in the rock mass) are considered optimal explosion parameters and are entered into the data bank. A detailed instrumental study of the structure of the rock mass by measuring the specific energy consumption of drilling for each blast hole allows you to have a clear picture of the actual distribution in the resistance space of the mass of the blasting block to the destructive effect of the explosion. The knowledge of this picture, as well as the parameters of the placement of borehole explosive charges with known energy and the exact times of the release of this energy by each charge in the space of the rock massif, will allow us to construct a mathematical model of the fracture mechanism of this particular block suitable for similar conditions. In addition, it becomes possible to verify the theoretical postulates of the ICWM on the mechanism of explosive destruction. The first of them requires the explosion of the next charge for 3-5 ms, while in the rock mass, the stress state from the action of the explosion of the previous charge is preserved, so that the summation of the voltages from the two charges occurs. The second requires blasting after 20 ms or more, so that a wide crack can be formed, playing the role of a new free surface, reflecting stress waves and increasing the quality of rock crushing in the region of the second charge. So far, these postulates have been tested on models of glass, plexiglass and other transparent materials in the laboratory.

According to the results of evaluating the properties and structure of the rock mass of the working blocks, they are divided into characteristic sections with the same or similar properties and the optimal parameters for blasting are selected for each such section from the accumulated data bank, including information about various rocks, charge structures, blast patterns, and explosion results.

Thus, the inventive method for determining the optimal parameters of explosive destruction of rocks will allow us to study the mechanism for the development of explosive explosive charges in real time directly in the rock mass, and not on models, and thereby solve the problem.

Sources of information taken into account when preparing the application.

1. Methods of controlling an explosion in quarries. - M .: Nedra, 1973.- 416 p.

2. Tangaev I. A. Energy intensity of the processes of extraction and processing of minerals. - M .: Nedra, 1986.- 231 p. (prototype).

3. E. B. Shevkun, N. A. Leonenko. Mobile explosive installation shelter: RF patent No. 2203478, MKI ⁷ , F 42 D 5/045, F 42 B 3/113, 2003.

Claims (3)

1. A method for determining the optimal parameters of explosive destruction of rocks, including measuring the specific energy consumption of drilling rocks during drilling of blast holes and calculating explosive charge parameters, patterns and deceleration intervals during their blasting, evaluating the results of an explosion with the energy intensity of rock excavation and selecting optimal parameters explosion according to statistics, characterized in that on the experimental blocks with the same array properties, several explosions are carried out with fixing the exact time of initiation of each on the explosive charge and build a model of the actual development of mass explosion in real time and space for a particular circuit design and blasting charges. 2. The method for determining the optimal parameters of explosive destruction of rocks according to claim 1, characterized in that when achieving rational results of the explosion, a combination of specific indicators of the properties of the array, the parameters of the charges and the sequence of their initiation in time and space are considered optimal parameters of explosive destruction for arrays with similar indicators properties and accumulate them in the database. 3. The method of determining the optimal parameters of explosive destruction of rocks according to claim 1 or 2, characterized in that the working blocks are divided into sections with the same properties of the array and the optimal parameters of explosive destruction are selected for each of them from the accumulated data bank.