SU1745930A1 - Chambered resources blasting method - Google Patents

Abstract

The invention relates to the mining industry and can be used in underground mining of mineral deposits by chamber systems with explosive blasting of reserves. The purpose of the invention is to improve the crushing of ore while reducing the seismic effect of explosions on the surrounding massif. Preparation of chambers for excavation consists in carrying out - The invention relates to the mining industry and can be used in underground mining of mineral deposits with chamber systems with explosive blasting of chamber reserves. There is a known method of developing minerals by a chamber system, which includes drilling of an array of deep wells and blasting ore by angular ledges by vertical layers, the drilling being performed by fans of drilling workings, the route of which corresponds to the concave shape of the cleaning space (angle, arc, etc.) , drilling the array with rows of parallel wells (C) and charging them with explosives (EIS) charges. The linear energy intensity of 33V in each row of arms C decreases as C approaches the boundaries of the chamber and is proportional to the distance to these boundaries. The change in the energy intensity of the ZVV is carried out using different types of explosives, a change in the design of the ZVV, diameter C, reduction in the number C in bundles, etc. The distance between the SIS in each row of C is also reduced as they approach the boundaries of the chamber in proportion to the distance to these boundaries. When reserves are crushed to the cleaning space, made in the form of an arc, the LNS value of each C p and d decreases as C approaches the boundaries of the chamber in proportion to the distance from C to these boundaries. The short-delay blasting of ZVV in each row of the ports begins with a ZVV adjacent to the ZVV furthest from the borders of the chamber. 1 hp ff, 2 ill. wells from the center of the chamber, and on the border with the pillars create a cutting gap. The disadvantages of the method are the uneven crushing and low ore yield of 1 meter of borehole, typical for fan drilling, as well as the need for additional costs for penetration of the cut-off slots along the boundary between the chamber pillars. The closest in technical essence and the achieved result to the proposed is a method of breaking chamber VI VI SL Y SO O

Description

reserves, including the drilling of a chamber array in rows of parallel wells and their delayed blasting onto a concave cleaning space in the form of an angle.

The disadvantage of this method is the low efficiency of crushing ore during blasting, due to the limitation of the linear energy intensity of the borehole charges due to the seismic effect factor, explosions on the surrounding massif and the stability of the elements of chamber development systems.

The purpose of the invention is to improve the crushing of ore while reducing the seismic effect of explosions on the surrounding massif.

The goal is achieved by the fact that in a method that includes drilling a chamber array in rows of parallel wells and their slow blasting into a concave treatment space, the linear energy intensity of charges in the wells of each row and the distance between them decreases as the wells approach the chamber boundaries is proportional to the distance to these boundaries, and the charges in the row are blown up sequentially, starting from adjacent to the charge farthest from the chamber boundaries.

In addition, when reserves are mined to the cleaning space, made in the form of an arc, the magnitude of the line of least resistance of charges in a row is reduced in proportion to the distance from these charges to the chamber boundaries.

Reducing the linear energy intensity of the charges in the wells of each row and the distance between them as the wells approach the chamber boundaries in proportion to the distance to these boundaries ensures a reduction in the seismic effect of explosions on the surrounding array and allows them to withstand the optimum specific flow rate B In for blasting charge, which improves the crushing of ore during blasting.

The successive blasting of charges in a row, starting from adjacent to the charge furthest from the chamber boundaries, allows the charges to the next to the boundary of the chamber to blow up to two outlines parallel to them, thus reducing the seismic effect of explosions on the surrounding area. massif and improvement of ore crushing due to a decrease in charge clamping. In addition, the provided blasting sequence provides an explosion of the charges farthest from the chamber boundaries with the highest linear energy intensity in a row into two additional outcrop planes parallel to these charges, which also drastically reduces the clamp

charges, seismic action of their explosions and improves the fragmentation of the battered array.

Reducing the magnitude of the line of least resistance of the charges in a series of proportional distance from these charges to the boundaries of the chamber while blasting reserves to the cleaning space, made in the form of an arc, allows an optimal ratio to be maintained between the linear energy intensity of each charge and its line of least resistance. , which contributes to the improvement of the crushing of beating passages.

FIG. 1 shows a camera with a corner

form of cleaning space; in fig. 2 - the chamber with the shape of the cleaning space in the form of an arc.

Designations adopted in FIG. 1, 2: 1 - IV, the succession of the fracture of the ledge by explosions of well charges, the numbers of which are given in numbers 1-4 as the linear energy intensity of the charges decreases.

The method is carried out as follows.

A cleaning chamber is being prepared. The preparation of chamber stocks for excavation consists in carrying out drillings of the horizon and drilling the array with parallel wells. Drilling Horta 5, passed along the boundaries of the chamber, are connected by drilling drifts 6, the route of which corresponds to the concave shape of the cleaning space (angle, arc, etc.),

Development of chamber stockpiles of starters with the formation of a cutting gap to the full height of the chamber and the formation of a concave clearing space. The breaking of ore into the treatment space is carried out in rows of borehole charges 1–4 (ledges).

The linear energy intensity of charges P in the row decreases as the charges approach the boundaries of the chamber PI 2 Рз Рл

and is proportional to the distance to these boundaries Li L2 La.

Changes in the linear energy intensity of charges can be achieved in various ways. When wells are charged with explosives of the same type with identical charge design and equal density of explosives in wells, linear energy intensity is reduced by reducing the charge diameter d or reducing the number of wells in beams parallel to the closely spaced well charges. When ore is blasted with single borehole charges of the same diameter, the linear energy intensity is reduced by reducing the density of explosives in the wells or using explosives with lower energy parameters.

The distance between the charges and also decreases as the charges approach the boundaries of the chamber ai ghz proportional to the distance to these boundaries Li L h.

When chamber stocks are crushed to an arc-shaped cleaning space, the magnitude of the line of least resistance of charges W in the row is not constant and decreases as charges approach the boundaries of the chamber Wj L / 2 L / r L / 4 also proportional to the distance from of these charges to the borders of the chamber Li La.

Short-delay blasting of charges in a row begins with sectors I (charge 2). Explosion of charges 2 creates an additional outcrop plane for charges 1 and 3. Then charges 3 and 4 explode in succession, beating off prisms II and 111. Zar d I, repulsing prism IV, explodes last in a row or simultaneously with charge 4.

The successive decrease in the distance between the charges as they approach the boundaries of the chamber provides the possibility of successively decreasing the linear energy intensity, charges without decreasing the specific energy B B for breaking. The consequent decrease in the linear energy intensity of charges reduces the seismic effect of explosions on the surrounding array. In addition, the prescribed sequence of blasting charges in a series allows for an additional increase in the free angle of charges 3 and 4, which significantly exceeds 90 °, which reduces the overall seismic effect of these charges and the effect of explosions on the surrounding array.

The explosion of charge 1 takes place on the outcrop surface formed by the explosion of charge 2. The base of the prism destroyed by charge 1 is 2 times or more above the line of least resistance of this charge, which ensures good crushing of the ore in the contours of the prism

normal crushing charge without increasing charge linear energy intensity and seismic explosion effect

The application of the proposed method allows to increase the fraction of the blast energy of the charges spent on crushing the array, and to reduce the fraction of energy, which appears in a competitive seismic form.

At the same time, there is an improvement in the crushing of ore and a reduction in the output of oversize by 25–30%, as well as a reduction in the destruction. impact of explosions on the surrounding massif (pillars). Reducing the seismic effect allows 70-75% of chamber reserves to be beaten off by parallel charges of high linear energy intensity, including charges of increased diameter and parallel well bore holes, which helps reduce the total length of the blast holes in the chamber 20-25%.

Claims (1)

1. A method of blasting chamber stocks, which includes drilling a chamber array in rows of parallel wells and their slow blasting into a concave treatment space, characterized in that, in order to improve ore crushing while reducing the seismic impact of explosions on the surrounding array, the linear energy intensity of the charges in each well The row and the distance between them decrease as the wells approach the boundaries of the chamber in proportion to the distance to these boundaries, and the charges in the row are blown up sequentially, starting from the adjacent ohm furthest from the edges of the camera A method according to Claim 1, characterized in that, when blasting reserves to a cleaning space made in the form of an arc, the magnitude of the line of least resistance of charges in a row is reduced in proportion to the distance from these charges to the chamber boundaries. Fig 1 22