RU2360117C1 - Method of pillar destruction - Google Patents

Abstract

FIELD: mining.

SUBSTANCE: invention can be implemented at development of mineral deposits by method of explosion for destructing between-chamber and under-goaf pillars of ore deposits, and also for block caving under conditions of increased mine pressure. The method of destruction of pillars consists in drilling boreholes in the pillar and in placing charges of explosion material EM in them, in driving upward boreholes and in placing chamber charges of EM in them, in successive explosion with formation of system of opposite relieving cavities into two opposite surfaces of pillar exposure and in final destruction of the pillar by explosion of the chamber charges of EM. Coaxially with project contours of reliving cavities additional boreholes are drilled. The additional boreholes are arranged symmetrically to the lengthwise axis of the pillar, and charges of EM are placed into them. Initially the relieving cavities are formed on ends of the pillar, further other cavities are formed. Charges of EM in additional boreholes located on ends of the pillar are exploded after formation of the relieving cavities. Simultaneous explosion of chamber charges of EM and charges of EM left in additional boreholes is performed last of all.

EFFECT: upgraded quality of crushing increased safety of mining.

4 dwg, 1 ex

Description

The invention relates to mining and can be used in the development of mineral deposits in an explosive way for the destruction of interchamber, sub-mine pillars of ore deposits, as well as floor collapse of blocks in conditions of high rock pressure.

A known method of destruction of pillars (patent RU No. 2046941, Е21С 37/00, F42D 3/00, 10/27/1995, bull. No. 30), in which the first steps to slow down the mass explosion form gaps with explosive charges located in the conjugate wells and subsequent blasting chamber explosive charges.

The disadvantage of this method is the uneven and low-quality crushing of the array in the alignment of the resulting cracks due to the low energy parameters of the explosion of explosive charges located in the conjugate wells, as well as the high costs of secondary crushing due to the negative effect of rock pressure on the results of the explosion.

The closest technical solution is the method of destruction of pillars (patent RU No. 2213222, Е21С 41/22, F42D 3/04, 09/27/2003, bull. No. 27), including drilling in the whole of the wells with the placement of explosive charges in them, sinking rebellion with the placement in them explosive chamber charges, sequential blasting with the formation of a system of opposite attenuating cavities on two opposite surfaces of the exposure of the pillar and the final destruction of the pillar by the explosion of chamber explosive charges.

The disadvantages of this method are low-quality crushing of the pillar array due to the negative influence of rock pressure on the results of an explosion of explosive charges, as well as provoking dynamic manifestations of rock pressure (rock blows) of high energy classes after a mass explosion, which reduces the safety of mining operations.

The single technical result of the present invention is improving the quality of crushing by reducing the energy intensity of the destruction of the pillar due to the formation of stress fields in the pillar array that promote explosive destruction, as well as increasing the safety of mining operations by reducing the likelihood of dynamic manifestations of rock pressure (rock blows) after a mass explosion. high energy classes.

The indicated unified technical result is achieved by the fact that in the known method for the destruction of pillars, including drilling in the pillar of the wells with the placement of explosive charges in them, sinking of the insurgents with the placement of chamber explosive charges in them, sequential blasting with the formation of a system of opposite attenuating cavities on two opposite surfaces of the exposure of the pillar and the final destruction of the pillar by blasting the explosive chamber charges, additional wells are drilled coaxially with the design contours of the attenuating cavities, and additional e wells are located symmetrically to the longitudinal axis of the pillar and place explosive charges in them, while initially forming attenuating cavities at the ends of the pillar, then the remaining explosive charges in additional wells located at the ends of the pillar explode after the formation of attenuating cavities, and the simultaneous explosion of chamber explosive charges and the remaining explosive charges in additional wells are carried out last.

Drilling additional wells coaxially with the design contours of the attenuating cavities symmetrically to the longitudinal axis of the pillar and the placement of explosive charges in them is designed to redistribute the energy of the explosion over the area of the pillar. Since after the initial formation of attenuating cavities in the ends of the pillar due to the redistribution of the maximum compressive stresses σ _max acting on the Siberian iron ore deposits from the ends of the pillar, the fields of tangential and tensile stress fields that are significant in magnitude and distribution are formed in the massif of the latter (see A.S. SU No. 1547476 "Method for explosive crushing of pillars", Е21С 41/00, F42D 3/04 (ДСП), 04/06/1988; Kvapil R. New views in the theory of rock pressure and rock blows. M .: Ugletekhizdat. - 1959. - С .67, fig. 21). Therefore, for the formation of the remaining attenuating cavities in the formed stress field, the mass of explosive charges can be reduced, since the fields of tangential and tensile stresses contribute to the explosive destruction of the material (Hanukaev A.N. Dynamic tensile strength during explosion under conditions of pre-stressed rock condition / A.N. Hanukaev, V.P. Belyatsky, A.A. Ionin // FTPRPI. - 1976. - N 2. - S. 49-53). That is, additional wells are drilled and explosive charges are placed in them due to savings in the formation of explosive charges to form attenuating cavities.

Explosive charges in additional wells located at the ends of the pillar explode after the formation of attenuating cavities, pursuing two goals. The first is the dynamic effect on the massif, in which, after the formation of all attenuating cavities, the fields of tensile stress fields significant in magnitude and propagation are formed (Seryakov V.M. Geomechanical substantiation of the parameters of borehole charges during breaking of a stressed massif / V.M.Seryakov, G.N. Volchenko // Physical and Technical Problems of Mineral Development, Novosibirsk: IGD SB RAS. - 2003. - No. 5. - P.23-29.). As a result of this effect, in the array exposed to tensile tensile fields, a low-energy fracture mechanism is realized due to a change in the type of fracture: from single-fracture in the region of quasistatic loading to multi-fracture in pulsed tension. As a result of this, an ensemble of simultaneously growing and interacting microcracks of high concentration is formed, pre-fracturing the massif (Belendir E.N. Resistance to destruction of rocks at loading times 10 ^-2 -10 ^-6 s. / E.N. Belendir, V.F. Klyatchenko , A.I. Kozarchuk, and others // FTPRPI. - 1991. - No. 2. - S.46-49). The second goal is a segment of the damaging array of the pillar from the host rocks, which will significantly reduce the amount of seismic energy burst into the host array after simultaneously blasting explosive chamber charges and remaining explosive charges in additional wells and the likelihood of provoking dynamic manifestations of rock pressure of high energy classes, which will increase safety mining operations (Impact hazard management of a mountain massif by changing the parameters of explosive blasting during the development of iron ore deposits of Si ..... Iran Abstract of a thesis ... of Doctor of Technical Sciences / Matveyev IF - SibPTU -. Novokuznetsk, 2004. - 34 c)..

The simultaneous blasting of chamber explosive charges and the remaining explosive charges in additional wells is carried out last. Explosions of explosive charges in additional wells orient the energy of explosions of chamber explosive charges to the boundaries of the pillar, located opposite weakening cavities. This orientation is based on the interaction of simultaneously explosive explosive charges (see, for example, Langefors U. Modern technique of explosive rock breaking / Langefors U., Kilstrem B. - M .: Nedra. - 1968. - P.245, Fig. 174) , which will guarantee a guaranteed and high-quality destruction of the remaining pillar array. Thus, the above-described impact on the pillar array of various static and dynamic stress fields determines its prefracture (attenuation), therefore, blasting the chamber explosive charges and the remaining explosive charges in additional wells is carried out with reduced energy characteristics of the explosion (reduction in the mass of explosive charges), and a segment of the destructive array the pillar from the host rocks will significantly reduce the amount of seismic energy splash into the host mass and the likelihood of provoking dynamic manifestations pressure of high energy classes, which will increase the safety of mining operations.

The proposed method for the destruction of pillars with the specified set of features ensures the achievement of a result in improving the quality of crushing by reducing the energy intensity of the destruction of the pillar due to the formation of stress fields in the pillar array that promote explosive destruction, as well as increasing the safety of mining operations by reducing the likelihood of provoking after a mass explosion dynamic manifestations of rock pressure (rock bumps) of high energy classes and has a significant novelty Noah.

The method for the destruction of pillars was implemented at the iron ore mine of the Abakan branch of Evrazruda OJSC.

An example of the implementation of the proposed method for the destruction of pillars is a special case when applying the system of floor forced collapse.

The essence of the technical solution is illustrated by the drawings, in which Fig. 1 shows the rear sight in plan, which shows, as an example, the arrangement of borehole and chamber explosive charges and the design circuit diagram of attenuating cavities. Figure 2 shows a diagram of the initial formation of attenuating cavities at the ends of the pillar during short-blasting. Figure 3 - diagram of the subsequent stage of the formation of attenuating cavities on two opposite surfaces of the exposure of the pillar. Figure 4 - diagram of the contouring of the pillar before its final destruction by the proposed technical solution.

The method is as follows. The whole 1 is drilled in rows of downhole wells 2 to form the design contours of the weakening cavities 3 on two opposite surfaces of the pillar exposure, the compensation chamber 4 and the rocks of the previously collapsed block 5. The locations of explosive chamber charges are determined using known methods (Viktorov S.D. ore deposits of Siberia / S.D.Viktorov, A.A. Eremenko, V.M. Zakalinsky, I.V. Mashukov. - Novosibirsk: Nauka. - 2005. - 212 p.). In these places there are uprising workings 6, for example, by sectional blasting of deep wells. Co-axially with the design contours of the attenuating cavities 3, additional wells 7 are drilled, the additional wells being located symmetrically to the longitudinal axis of the pillar 1 at the distance of the design line of least resistance with respect to the exposed surfaces of the pillar 4, 5. After drilling 2, 7 and drilling of the uprising mine workings 6 begin to create elongated explosive charges in wells 2, 7 and chamber explosive charges in the rising workings 6.

Explosion of explosive charges 2, 6, 7 is carried out by short-delayed blasting in the following sequence. Initially, weakening cavities 3 are formed at the ends of the pillar by an explosion of charges 2, as shown in FIG. Then, in the formed field of tangential and tensile stresses, borehole charges BB 2 are initiated to form the remaining attenuating cavities 3 according to FIG. 3. After the formation of all attenuating cavities 3, explosive charges are blown up in additional wells 7 located at the ends of the pillar, for additional dynamic impact on the array and segments of the damaging array of the pillar 1 from the host rocks, as shown in FIG. 4. Last of all, simultaneous blasting of chamber charges of explosive 6 and the remaining explosive charges in additional wells 7 is carried out.

The proposed arrangement of explosive charges in their entirety and the sequence of their blasting provides an increase in the quality of crushing by reducing the energy intensity of the destruction of the pillar due to the formation of stress fields in the pillar array that promote explosive destruction, as well as increasing the safety of mining operations by reducing the likelihood of dynamic manifestations of rock mining after a mass explosion pressure (rock blows) of high energy classes.

The proposed method for the destruction of pillars is industrially applicable in the mining industry during explosive crushing of minerals by borehole and chamber explosive charges.

Claims (1)

The method of destruction of pillars, including drilling in the whole of boreholes with the placement of explosive charges in them, sinking of explosives with the placement of chamber explosive charges in them, sequential blasting with the formation of a system of opposite attenuating cavities on two opposite surfaces of exposure of the pillar and the final destruction of the pillar by blasting of chamber explosive charges, characterized the fact that additional wells are drilled coaxially with the design contours of the attenuating cavities, and additional wells are located symmetrically to the longitudinal axis c spruce and place explosive charges in them, while initially forming attenuating cavities at the ends of the pillar, then the rest, explosive charges in additional wells located at the ends of the pillar, explode after the formation of attenuating cavities, and the simultaneous explosion of chamber explosive charges and the remaining explosive charges in additional wells are carried out last.

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