SU1666708A1 - Method of development of ore deposits - Google Patents

Abstract

The invention relates to the mining industry and can be used in underground mining of ores on steeply dipping low-power conductors. The goal is to increase the safety of work by reducing the impact hazard in the marginal part of the ore massif being worked out / PM /. After penetrating the subsurface mine (MF) and forming the substage of the PM, it is mastered and by blasting the explosive charge it is broken into the MF. The height of the substage is determined by the mathematical relationship taking into account the parameters of the stress state, due to the heterogeneity of the PM, the thickness of the ore body, the properties of the rock mass, the depth of development, the size of the PM and the coefficient of ore loosening. Broken ore is being mined. Then the subsequent sublevel development is carried out and the cycle for ore blasting and storage is repeated. A recess below the floors is carried out in a descending order. After all the reserves of the block have been crushed, the baffling and mazaged mountain mass is released. 3 il.

Description

The invention relates to the mining industry and can be used in underground mining of ores on steeply dipping low-power conductors.

The aim of the invention is to increase safety of work by reducing the impact hazard in the marginal part of the ore mass to be worked out.

FIG. 1-3, the vertical projections of the sewage treatment works into the block, respectively, are presented in the stage of smoking the ore massif of the substage, ore storage and release of the broken rock mass from the block.

The method is carried out as follows.

The block is prepared for clearing the excavation by driving the floor drifts of the ventilation and haulage horizons 1, the ore flanking rebels 2, and from one rebel rising along the strike of the reservoir a cut-off subsurface development 3 is located at a distance h from the marginal part of the reservoir, defined by the ratio

(KN / H + 1.65m ()).

where h is the height of the substage, m;

a is an empirical coefficient characterizing the change in stresses and associated with the heterogeneity of the ore mass:

K is an empirical coefficient depending on the thickness of the ore body:

N is an empirical exponent, taking into account the physical and mechanical properties of the rock mass;

H is the depth of management of cleaning operations, m;

F is the cross-sectional area of the sub-floor excavation, m;

m - extraction capacity of the ore body, m;

Кр - coefficient of ore mass loosening.

The subsurface formed in this way (ore pillar) is filled with 3 sets of bore-holes or boreholes from the subsurface mine 4. The explosive cavities are charged with explosive charges and the blasting of charges makes the ore mass in the sub-floor. The blasting is made at subsurface mine 3, which serves as a compensation space necessary to give the ore 5 being mined sufficient loosening.

After the ore has been stored on the sub-floor, the next sublevel production is made and the next sublevel is formed with a height determined by the reduced ratio.

Work on cutting and excavating the stocks of each subsequent floor is performed in the specified sequence.

Repulsed rock mass is released after blasting all reserves of the block, for example, through generation of output 6.

Claims (1)

Invention Formula The method of development of ore deposits, including the penetration of subsurface block workings, ore mass mining from subsurface mine workings, excavation of ore under floors in a descending order, breaking of the ore massif in a sub-floor to the sublevel mining, sublevel ore mining and production of broken rock mass, characterized in that, in order to increase safety work by reducing the impact hazard in the edge part of the mining massif, the ore is removed by sub-floors with a height determined from the ratio (+ 1.65t ()). where h is the height of the substage, m; a is an empirical coefficient characterizing the change in stresses and associated with the heterogeneity of the ore massif; K-empirical coefficient, depending on the thickness of the ore body; N is an empirical exponent, taking into account the physical and mechanical properties of the rock mass; H is the depth of management of cleaning operations, m; F is the cross-sectional area of the sub-floor excavation, m; m - extraction capacity of the ore body, m; Cr is the coefficient of loosening of the ore mass, depending on the properties of the ore and the method of blasting, each subsequent sublevel production takes place after the ore has been stored in the previous substage, and the broken rock mass is released after all block reserves have been broken. 0 five 0 five fe3 Compiled by A.Loginsky Editor L.Narodna Tehred M.MorgentalKorrektor E.Lonchakov Order 2507 Circulation 310 Subscription VNIIPI State Committee for Inventions and Discoveries at the State Committee on Science and Technology of the USSR 113035, Moscow, Zh-35, 4/5 Raushsk nab. Production and Publishing Combine Patent, Uzhgorod, Gagarin st., 101 fe3 Corre