SU1661422A1 - Method for working inclined ore obstructions - Google Patents

Abstract

This invention relates to the development of medium thickness ore deposits. The goal is to reduce the amount of preparatory work. The development of the deposit is carried out in sublevels with ore and field workings. Ore extraction on subsurfaces is carried out by cameras along strike with the design of tape intercameral subsurface pillars. Along the chambers, transport sublevel workings pass along the ore; a cutting slot is formed in the middle part of the chamber. At the bottom of the chamber, ore receiving funnels are formed, which are knocked down with transport workings by ortami. The cutting of ore is made from the transport drift from the cutting slot to the flanks of the chamber along the strike of the deposit by drilling and blasting wells into the cutting slot. Repulsed ore produced. On the flanks at the boundaries of the chambers, drilling niches with a length equal to the width of the sub-floor pillar extend. The distance between the drilling holes and the running output, passed from the transport drift across the deposit with the entire protection above it, is assumed to be equal to the length of the longitudinal wells. The latter are drilled by fans in a tape subsurface pillar from the roadway and drilling niches towards each other. The breaking of the indicated wells is carried out after complete extraction of the reserves of the substage in the direction across the strike along the landing of the roof. Repelled ore pillars produced. In addition, the road workings are driven from the field transport drift of the overlying substage through the rear sighting pillar of the underlying substage before connecting with the camera of this substage. 1 hp ff, 8 ill.

Description

The method is carried out as follows.

The inclined ore deposit within the floor is divided into blocks, which in turn are divided into long horizontal stripes (substages), located along the strike of the deposit and including extraction chambers, processed along the strike, and enclosing their tape supporting sublevel pillars. The preparatory work consists of carrying out transport drifts 1-3 on the sub-floors, along the excavation chambers. From the traffic drifts of each underlying substation in the direction of the adjacent overlying substage, horizontal running holes 4 and 5 pass across the deposit to the border between the sublevels, and in barrier pillars located on the flanks of the chamber, short drill holes 6 are equal in length to the fencing tape pillars. Short transverse loading orts 7 pass between running excavation 4 and drill hole 6. In this case, the distance between running excavation 4 and drilling niche 6 within each sub-floor is taken to be equal to the length of the belt pillars from these wells running towards each other. The running openings 4 and 5, located on different sub-floors, are knocked together by short rising embankments 8. After the completion of the specified preparatory work, they start the cleaning work.

The clearing recess begins with a cut-off slot in the middle part of the chamber. For this, a short cut-off end 9 is passed from the transport exit 1 across the extraction chamber 9. Upward wells 10 reach the roof of the excavation chamber from the cut-off generation 9 and by detonating explosive charges in these wells beat off ore. At the same time, after each crushing of the ore, the ore store located in the gap is partially unloaded. Having formed a certain compensation space, from the transport drift 1, passed through the ore, the wells 11 are drilled. The ore is blasted to the cutting gap by blasting explosive charges in the fan sets of wells 11 along the extending deposit. After a number of ore layers have been crushed in the chamber from the loading orts 7, connected to the transport drift 2, the fan of the boreholes 12 is formed. to the chamber flanks. Through the ore-receiving funnels formed in this way, the broken ore is released using loading and hauling equipment, and further along the transport drift is delivered to the ore landing. In the process of excavating chamber stocks and forming funnels above the road workings 4 and 5, protective pillars 13 of a prismatic shape are formed in the soil of the chambers, preserving the road workings 4 and 5.

After the chamber stocks are fully excavated within the substage range, the belt pillars are drilled with fans of wells from the cutting output 4 that cuts through the pillars. The drilling equipment is delivered from the transport drift 2 along the track 5 and the rising tail 8. The belt pillar is drilled on both sides of the track making 4 fans of wells 14 along the pillar, and from the drilling niches 6 we drill counter fans of the wells 15. After charging the wells 14, 15, the ore is crushed in the pillars across the strike and the ore from the ribbon and osvobodivshies rudopriemnye funnel. After destroying the ribbon sight and filling the ore receiving funnels with the broken ore, they form a sufficiently large area of the exposed roof that is crushed. Since the ore is blocked off from the ribbon pillar, all the output chambers entering the developed space are excluded, any negative consequences are possible from the air strikes caused by the collapse of the roof rocks.

In the case of using the scraper equipment opposite the loading units 7, the scraper niches 16 are designed in which the scraper winches are installed. Repulsed ore is released and from the scraper orts 7 are transported to the transport (scraper) tunnel 2 and then the ore is scraped up along this roadway to the ore-landing located on the flank of the block,

In addition, the developed inclined ore deposit within the block is divided into sub-floors located along the strike of the deposit and including excavation chambers and protecting tape pillars. Preparatory work includes carrying out transport drifts 17 in each sub-floor in the soil of a deposit and drilling drifts 18 in excavation chambers. Transport drifts 17 and boring drifts 18 knock together transport ports 19, passed on the flanks of the block. From the traffic drifts 17 of each overlying substage in the direction of the adjacent underlying substage, the undercarriage

generation 20 through the tape sub-floor pillar of the underlying substage to the camera with this substage. In this case, the distance between the running output 20 and the transport unit 19 within each substage is assumed to be equal to the length of the fencing of the fence pillar in the fans of the longitudinal wells from these openings towards each other.

Between the running openings 20 and transport ports within each substage, loading ports 21 under the excavation chambers to the border of the adjacent underlying substage pass. Clearing the excavation chamber stocks are simultaneously on several sub-floors independently of each other. The breaking of ore within the excavation chambers is carried out by blasting explosive charges in fan sets of wells drilled from borehole 18.

The design of the ore receiving funnels in the bottom of the chambers is carried out from the loading units as the chambers are mined. Through the ore receiving funnels, the broken ore is taken from the end of the loading units 21 by means of loading and hauling machines and further along the transport drift 17 is delivered to the ore pass. At the same time, in the process of cleaning the excavation of chamber stocks above the undercarriage 20 in the soil, chambers of prismatic shape are formed by the chambers, which preserve this production from destruction.

After working the chambers within the block, the fencing tape pillars on the sub-floors are smoked. Out of a running production 20 that cuts through a fence tape pillar, we drill fans of longitudinal wells 22 on both sides of these workings, and from transport links 19 on the flanks of the block we drill counter fans of longitudinal wells 23. Work on fence pillars of pillars consistently from above way down. After charging the wells, the ore is blasted and exploded with it thrown into the released ore receiving funnels. Having destroyed the enclosing tape pillar and filling the ore receiving funnels with broken ore, they form a sufficiently large cavity of the roof exposing, which collapses - after the broken from the tape pillar.

Claims (2)

1. Method of development of inclined ore deposits, including mining deposits in sublevels with the conduct of ore and field workings, excavation of ore in the sublevels chambers along the direction with the formation of belt inter-chamber subsurface pillars, carrying out transport sublevel workings along the chambers, design of running horizontal workings, cutting slots and ore receivers at the bottom of the chambers, coupling the funnels with transport workings ortami, breaking the ore in the chambers along the strike direction by drilling and blasting wells into the cutting gap, will release the main ore reserves, the drilling of inter-chamber subsurface pillars by fans of wells, their breaking with simultaneous landing of the roof and the production of broken ore of pillars, characterized in that, in order to reduce the preparatory work, the cutting gap passes in the middle part of the chamber, the ore is produced from the transport drift traversed by ore, from the cutting slot to the flanks of the chamber, where drilling niches with a length equal to the width of the sublevel bottom pillars pass along the chambers border, and the distance between the drilling niches and the chassis mended traveled by the vehicle from the roadway across the strike the deposits are assumed to be equal to the length of the longitudinal wells, which are drilled in the belt sublevel pillar from the roadway and drilling niches towards each other, the breaking of the said wells is done after complete extraction of the substage in the direction of the spread of the reservoir, and in the process of formation of ore receiving funnels in the soil The cameras above the roadways are formed by security pillars. 2. The method according to claim 1, characterized in that the penetration of the road workings is made from the field transport drift of the overlying substage through the belt the sub-floor pillar of the underlying sub-floor before the camera of this sub-floor. iV 18 777 6 AND III and L / N Sh 73 2021 7 t / 5 q 2/2 / / 7 te, 9