SU1765401A1 - Rock pressure control method - Google Patents

Abstract

This invention relates to the underground mining of high-power, half-falling ore deposits. The goal is to increase the reliability of maintaining the roof of the open space due to the redistribution of rock pressure to the combined laying of the second-stage chambers and increasing the load-bearing capacity of the material of the bookmark as a result of its active compaction under the action of the rock pressure. The first-stage bands are divided into first and second-stage chambers. The chambers of the first stage are filled with hardening mixtures. The chambers of the second stage are partially filled with a hydraulic folding, and the remaining part — with collapsed roof rocks with filling of the forming space along the dome of the collapse roof. Hardening mixtures are fed to the broken rocks. In the rocks of the roof of these chambers on the borders with strips of the second stage form pedigree separation pillars. The side surfaces of the pillars are designed with a slope in the direction of the vertical axis of the bands of the first stage. With the collapse of the roof rocks in the bands of the second stage, the inclined walls of the separation pillars are formed from the side of the worked bands of the second stage 2 mud. SO with

Description

The invention relates to the mining industry and can be used in the management of rock pressure in the underground mining of powerful gently dipping ore deposits.

There is a method of controlling rock pressure, which includes dividing excavation areas on the panels of the first and second stages, working out the panels of the first stage and setting them, working out the panels of the second stage and after reaching a given strength of the bookmark - panels of the first stage, and laying down panels of the second stage. The developed space around the subject

the excavation of the ore massif is filled with collapsed rocks or bookmark; the ore massif is divided into excavation ribbons. Artificial and natural supports are formed in each tape, and opposite supports of one type are placed in mutually perpendicular directions, then the panels of the second turn are worked out and laid on the sections of artificial supports. After a set of the specified strength of the bookmark in the central part of the artificial array of spent panels of the first and second stages, the excavations in the panels of the second stage are made and after the redistribution

(L

s

dividing the rock pressure into artificial pylons extracts reserves from the natural pillars of these panels. At the same time, in order to increase the compliance of natural supports from the workings of panels of the second stage, the wells are drilled mainly in minerals, and when the mineral deposits are gently sloping, the ore massif is divided into panels of two standard sizes, in the smaller ones natural ones are formed.

The disadvantage of this method is a decrease in the reliability of maintaining the overlying stratum of rocks when extracting stocks of secondary panels and, therefore, possible disturbances of artificial supports.

There is a method of controlling rock pressure, which involves dividing the excavation field into parallel strips, which from the cutting line work out in two stages: initially, the primary strips with the laying of the worked-out area are worked out using the chamber-cell system, then, with some delay, the secondary strips are dredged systems with collapse. In the primary lanes, chambers of the first and second stage are separated. The chambers of the first stage work by filling them with a hardening tab, the chambers of the second stage after excavating the mineral are partially filled with a hydraulic bookmark, and in the remaining part they collapse roof rocks with a filling of the resulting space over the dome of the collapse roof and inject the crushed rocks with hardening mixtures. The developed space of the strips of the second stage is filled with roof rocks, which are destroyed with the advance of the cleaning works in these strips.

However, this method is characterized by insufficient safety and reliability of maintaining the overlying rock mass, which means that when the roof rocks collapse in the secondary strips, the injected rocks of the second stage in the primary strips are exposed, which can lead to their collapses under the influence of blasting operations. the space of the secondary bands, violating the carrying capacity of the primary bands.

The aim of the invention is to increase the reliability of maintaining the roof of the developed space due to the redistribution of rock pressure to the combined laying of the chambers of the second stage and increasing the carrying capacity

material of the bookmark as a result of its active compaction under the action of rock pressure.

The goal is achieved by the method of controlling rock pressure, which includes filling chambers of the first stage with a hardening bookmark and partially filling the chambers of the second stage with a hydraulic bookmark with subsequent collapse of the roof rocks and filling the resulting space in the dome when working out in two stages with advanced strips of the first stages by cameras of the first and second stages,

injection of collapsed rocks with hardening mixtures and maintenance of the developed space of the bands of the second stage by filling it with the collapsed rocks to the height of the ore deposit to be removed

after filling the chambers of the second stage in the bands of the first stage with a hydraulic laying, in the rocks of the roof of these chambers on the borders with the bands of the second stage form breed separating

pillars, while the side surfaces of the pillars are formed with a slope in the direction of the vertical axis of the strips of the first stage, when filling the developed space above the chambers of the second stage, the formed pillars tamp down the collapsed roof rocks, and then inject them with hardening mixtures, and when the roof rocks collapse the slopes of the second stage are sloping walls

dividing pillars from the side of the second stage.

Figure 1 shows the order of operation; figure 2 - section aa in figure 1.

The excavation area is divided into strips of primary 1 and secondary mining 2. The strips of the first stage are divided into chambers, which are processed and laid down with hardening mixtures 3 through one. Then in

The same strips are worked out by chambers of the second stage 4, which are half filled with hydraulic folding 5, and the remaining part is filled with collapsed roof rocks 6 filling the resulting space along the dome of the collapse. In order to strengthen the collapsed rocks, a certain amount of hardening mixtures is supplied to them. When rock breaks over the chambers of the second stage 4, the blasting boundary at the junction of the excavation strips is mixed deep into the primary strips, thus dividing the rear sight 7 between the collapse zones, and the edges 8 of the formed space are inclined from the secondary strips to the vertical axis

In order to unload from the reference pressure, the clearing zone, when excavating the secondary strips, preliminarily collapses the roof rocks, 25–30 m ahead of the ore blasting boundary. The ore is crushed under the collapsed roof rocks.

Thus, in the spent part of the deposit, the rock pressure is redistributed to the design described above of the primary chambers inherent in the chambers. The lanes of the second stage are fulfilled with a lag of 50-70 m from the lanes of the first stage.

Example.

The deposit of disseminated ores lies at a depth of 500 m and its average thickness is 40 m. In most of its area, the deposit is undermined by dredging solid ores with an average capacity of 35 m (the spent voids are embedded with an average strength of 4 MPa, which is characterized by a time outbreak in core samples when tested, they give strength up to 8 MPa). The width of the bands of the first stage is 80-100 m, the width of the bands of the second stage is not less than 100 m. In the process of excavating the bands of the second stage, regular forced collapse of the roof rocks to a height not less than the thickness of the deposited ores is necessary. The boundary of blasting roof rocks above the chambers of the second stage in the primary strips is shifted deeper by an amount not less than 10 m. When the chambers of the second stage are filled at half the power, i.e. at 20 m and the coefficient of loosening of roof rocks, equal to 1.35-1.5, it is necessary to blow them up to a height of 60-40 m. The boards of the formed space from the side of the secondary strips are inclined towards the vertical axis of the primary strips at an angle of 75-80 °. Hardening mixtures must be fed until voids in the collapsed rocks are filled along the top of the ore body.

Claims (1)

Claim Method Controlling Rock Pressure including filling the first-stage chambers with a hardening tab and partial filling of the second-stage chambers with a hydraulic tab, followed by the collapse of the roof rocks and filling or the space formed along the dome of the vault when mining in two stages with advanced testing of the first stage chambers of the first and second chambers, injecting the collapsed rocks with hardening mixtures and maintaining the developed space of the second stage lanes by filling it to the height of the ore deposit of the collapsed roof of the roof, characterized by what with in order to increase the reliability of maintaining the roof of the open space due to the redistribution of rock pressure to the combined laying of chambers of the second stage and increasing the bearing capacity of the material of the bookmark as a result of its active compaction under the action of rock pressure after filling the chambers of the second stage in the first stage bands with hydraulic laying in the roof rocks These chambers at the boundaries with strips of the second stage form pedal separation pillars, while the lateral surfaces of the pillars are formed with a slope towards the vertical axis of the strips of the first stage, with filling the excavated space above the chambers of the second stage, the formed pillars are teased by the collapsed rocks of the roof, after which they are injected with hardening mixtures, and when the roof rocks collapse in the bands of the second stage, the inclined walls of the separation pillars are formed from the side of the processed bands of the second stage. five (Dual