EA002524B1 - Method for working thick gentle ore deposits - Google Patents

Abstract

1. A method of working thick gentle ore deposits, including working an upper part of an ore deposit by board-and-pillar mining with panel preparation, extraction of ore in chambers, formation and then extraction of interchamber pillars, and roof fall of top rocks to a goaf; working a lower part of the ore deposit with extraction of its reserves by sublevel caving with butt-end drawing of ore under broken-down top rocks, wherein said formation of interchamber pillars is performed in an actual mining zone in which a pressure on the interchamber pillars does not exceed 30-35% of the total pressure acting on the interchamber pillars, said total pressure being calculated with the proviso, that the interchamber pillars will be preserved during the period of extraction of chamber reserves of the panel, and subsequent extraction of the interchamber pillars is performed mini the pressure acting thereon will reach 35-45% of the total pressure acting on the interchamber pillars, said total pressure being calculated with the proviso that the interchamber pillars will be preserved during the period of extraction of chamber reserves of the panel, said sublevel caving being lagged behind the board and pillar mining by at least one chamber filled with the broken top rocks. 2. The method according to claim 1, wherein said working of an upper part is performed with mounting a flexible separating cover on the goaf floor, and said butt-end drawing of the ore below the broken-down rocks is performed under the flexible separating cover.

Description

The invention relates to the field of mining and can be used in underground mining of ore from deposits whose reserves are localized in shallow deposits of high power, located at medium and large depths, in conditions of high rock pressure.

A known method for the development of shallow ore deposits, including the excavation of preparatory workings dividing the deposit into mining panels, mining of ore in mining panels by chambers with the formation of interchamber pillars in the treatment area, the extraction of pillar pillars and the collapsed rocks filling the mined chamber space (Copyright 8I No. 1608345 A1 , IPC 5 Cl. E 21C 41/16 published on 11.23.90).

The disadvantage of this method is that when developing deposits of high power, due to the significant height of the worked out space, difficulties arise in controlling the rock pressure, and, as a result, the safety of mining operations is reduced.

There is also a known method for the development of shallow ore deposits, including ore mining in mining panels by chambers with the formation of columnar inter-chamber pillars in the treatment area, subsequent extraction of pillars and filling of the worked chamber space with collapsed rocks, and inter-chamber pillars forming in the treatment cavity, in which pressure is applied to them does not exceed 30-35% of the total pressure calculated on condition that they remain for the period of extraction of the chamber reserves of the panel, and the subsequent extraction of interchamber pillars about exist until they reach a pressure of 3545% of the total pressure acting on them, calculated on condition that they are maintained for the period of extraction of chamber reserves of the panel (EAPO patent No. 001183, IPC class 6 E 21C 41/22, publ. 30.10.2000, EAPO bulletin No. 5 (2000)).

The disadvantage of this method is its relatively low efficiency in the development of powerful dipping deposits.

The closest in technical essence and the achieved result is a method of developing powerful shallow dipping ore deposits, including mining the upper part of the ore deposit by a chamber-pillar mining system with panel preparation, excavation of ore in the chambers, formation and subsequent excavation of inter-chamber column pillars and collapse of the overlying rocks in the worked out space , development of the lower part of the ore deposit with the extraction of its reserves by a sub-floor collapse with an end ore output under the collapsed overburden Oodi (Copyright certificate 8I No. 1273564 A1,

IPC 5 C, E 21C 41/22, published on 11/30/86

Bull. No. 44).

The disadvantage of this method is the relatively high risk of mining, due to the significant height of the developed space during the development of a powerful sloping ore deposits and the presence of a ceiling between its spent upper and lower parts.

The problem to which this invention is directed, is to create a development system that would ensure high-performance ore mining from dipping ore deposits of high power at medium and large depths under high rock pressure with minimal losses in the subsoil and creating safe mining conditions .

The technical result obtained in this case is to increase the safety of mining operations in conditions of high rock pressure while ensuring the completeness of the extraction of mineral reserves.

The specified technical result is achieved by the fact that in the known method for the development of powerful shallow dipping ore deposits, including the development of the upper part of the ore deposit by a chamber-pillar mining system with panel preparation, excavation of ore in the chambers, formation and subsequent excavation of interchamber column pillars and collapse of the overlying rocks into the mined-out space , development of the lower part of the ore deposit with the extraction of its reserves by a sub-floor collapse with an end ore output under the collapsed overlying rocks, with According to the invention, the formation of interchamber pillar pillars is carried out in the area of the treatment recess, in which the pressure on them does not exceed 30-35% of the total pressure acting on the interchamber pillars, calculated on condition of their preservation for the period of excavation of the chamber reserves of the panel, and the subsequent extraction of the interchamber pillar pillars is carried out until they reach a pressure of 35-45% of the total pressure acting on the interchamber pillars, calculated on condition that they are maintained for the period of extraction of the chamber reserves of the panel, while odetazhnoe collapse lead to lag relative to the chamber-pillar mining system, at least one chamber filled with caved overlying rocks.

And also by the fact that the development of the upper part is carried out with the installation of a flexible separating overlap on the soil of the worked out space, and the end production of ore under collapsed rocks is carried out under a flexible separating overlap.

Each of the features of this combination is necessary, and together they are sufficient to achieve the obtained technical result in all cases of using the invention. In particular: the formation of inter-chamber pillars in the area of the treatment recess, in which the pressure on them does not exceed 30-35% of the total pressure acting on the inter-chamber pillars, calculated under the condition that they remain for the period of excavation of the chamber reserves of the panel, due to the fact that, since this zone it is partially unloaded by the edge of the deposit (face), the formed interchamber pillars experience less load and the probability of their sudden destruction is reduced.

Taking into account the fact that the pressure on the interchamber pillars depends on the time of their standing, in the initial period, the interchamber pillars do not experience pressure from the total weight of the overlying column of rocks (total pressure). Therefore, the extraction of inter-chamber pillars during the period when the pressure on them does not exceed 3545% of the total pressure also improves the safety of mining operations.

The lagging development of the lower part of the ore deposit by sub-floor collapse provides mining operations without entering the treatment space, and, in addition, the mountain pressure in the lower part of the deposit is reduced due to overwork.

The method of developing powerful gently dipping ore deposits is as follows.

The upper part of a powerful gently dipping ore deposit by sinking preparatory workings, for example, panel drifts or unit vectors, is divided into excavation panels. Preparatory workings pass through the ore mass. It is preferable to work out the upper part of the deposit in the direction from one flank of the deposit to another flank. Under favorable development conditions, as well as for the intensification of the cleaning recess, each excavation panel can be divided into sections that work out simultaneously with a slight lag from each other, forming a stepped front.

The dimensions of the extraction panels and chambers are determined from the condition of minimizing the cost of developing the deposit. Calculate the total pressure of the overlying rocks acting on the interchamber pillars of the panel, provided that they remain for the period of excavation of all chamber reserves of the panel without collapse of the overlying rocks. Based on the calculated total pressure, determine the dimensions of the inter-chamber pillars.

In case it is supposed to face the ore output using a flexible separating overlap to prevent penetration of overburden into the ore produced during mining of the lower part of the deposit, before mining the panel in its flank part from which mining will begin, preferably at the contact of the ore deposit with the side rocks, draw up a vertical or inclined slotted working out, in which then a flexible dividing overlap is installed.

The ore’s cleaning recess in the panel is driven by chambers with the formation of interchamber column pillars in the treatment recess zone, in which the overburden pressure on the interchamber pillars is 30-35% of the total pressure acting on the interchamber pillars, calculated on condition that they remain for the period of excavation of the chamber chamber reserves. The formation of interchamber column pillars in this zone allows them to be formed with a reduced cross-section as compared to the calculated cross-section, which, when finely drilled, allows them to be drilled only from the faces of the chambers, which increases the safety of extraction of interchamber column pillars, since the equipment in this case is located in a safe technological space zone. In addition, such pillars allow you to increase the active reserves of the camera, which can be extracted using high-performance equipment.

Ore extraction in the chambers is carried out using drilling and blasting operations (BWR) with self-propelled drilling and delivery equipment. Ore breaking can be done by tapping, ceiling tapping or continuous slaughter at the full capacity of the upper part of the deposit. The formation of interchamber column pillars is carried out by fine-blasting breaking of the ore massif of the chamber with the use of cartridge or alluvial explosives. In the latter case, pneumatic chargers can be used to charge the holes. The delivery of the beaten ore is carried out using self-propelled equipment along a panel drift or unit load to the ore-producing shaft or storage bin.

After ore extraction, a flexible dividing ceiling can be mounted in the chamber on the basis of the worked out space. When installing a flexible dividing floor, laid in the first chambers of the tested panel, it is connected to a flexible floor mounted in a vertical or inclined slotted working.

After excavating at least two chambers and forming two rows of interchamber column pillars, they begin to excavate the ore in the third chamber and extract interchamber column pillars in the first chamber. In this case, the extraction of interchamber pillar pillars should be made during the period when the developing pressure of the overlying rocks on the extracted interchamber pillar pillars does not exceed 35-45% of the total pressure acting on the interchamber pillars calculated if they are preserved for the period of excavation of the chamber reserves of the panel.

Extraction of interchamber column pillars is carried out by fine-blasting blasting in one go with short-delayed blasting. The broken ore by means of self-propelled delivery vehicles with remote control through the technological space of the adjacent chamber is delivered via a panel drift or unit to the ore-giving shaft or storage bin. A directional explosion can be used to place a pile of blasted ore from interchamber column pillars as close as possible to the mining face of the chambers.

Extraction of interchamber, columnar pillars initiate the collapse of the overlying rocks and filling them with the developed chamber space. In case of freezes, they are eliminated by forced collapse. To do this, a number of holes or boreholes that charge explosives and explode are drilled from the developed chamber space into overlying rocks at the border with hovering.

Before collapse of the overlying rocks, the technological chamber space is isolated from the space that will be filled with collapsed rocks, insulating jumpers. Such insulation will prevent the filling of the technological space with collapsing rocks and the need for its cleaning for the passage of self-propelled equipment.

Ore excavation in the lower part of the ore deposit is carried out by a sub-floor collapse with an end outlet. The sub-floor is divided by the width of the panel. Each panel is prepared by boring delivery (ort or drift). Drilling workings pass in the ore massif on the soil of the deposit or in the underlying rocks and are oriented parallel to the preparatory workings, passed in the upper part of the ore deposit.

From the drilling workings, fans of uprising wells are drilled, charged with explosive charges and blasted. Blasting is performed sequentially in a descending order by vertical or inclined sections. The next wells are blown up after the release of the main part of the ore from the previous blasting. Ore left on the soil of the mined chamber space, including that left after breaking off interchamber column pillars, may also be involved in the release.

The tilt angle of the section is selected depending on the ratio of the size of pieces of broken ore and pieces of collapsed overlying rocks. If the ore has a larger size than the collapsed overlying rocks, the slope of the section is taken towards the collapse. If the ore has a smaller fineness of pieces, the slope of the section is taken in the direction of the ore mass. With equal coarseness of pieces of ore and rock, blasting is carried out in vertical sections. When using a flexible dividing floor, the slope of the sections is selected based on the condition for maintaining the continuity of the flexible dividing floor.

Sub-floor collapse is carried out with a lag in relation to the development of the overlying part of the ore deposit, at least one chamber filled with collapsed overlying rocks. Those. the chamber located above the beating section, and at least one chamber following it in the direction of mining should be filled with collapsed overlying rocks.

As sections break down, the boring supply is paid off. The release of chipped ore is carried out through the ends of the boring delivery workings by self-propelled loading delivery machines. As the chipped ore is released, the worked-out space is filled with rocks collapsed during mining of the upper part of the deposit. The contact between the ore being produced and the collapsed rocks is maintained by observing the output planogram or by a flexible dividing overlap, which drops as the ore is released.

The ratio of the heights of the worked-out spaces of the upper and lower parts of the mined ore deposit is selected based on the rock pressure existing in the massif. In this case, the following condition must be met: the higher the rock pressure acting in the massif, the smaller the height of the worked out space should be when mining the upper part of the deposit.

The use of this invention allows to solve the problem of ensuring high-performance ore mining from dipping ore deposits of high power, at medium and large depths under high rock pressure with minimal losses in the bowels and creating safe mining conditions and to obtain the specified technical result.

Claims (2)

CLAIM 1. A method of developing powerful shallow dipping ore deposits, including mining the upper part of the ore deposit with a chamber-pillar mining system with panel preparation, excavating the ore in the chambers, forming and subsequently excavating the interchamber column pillars and collapsing the overburden into the worked out space, mining the lower part of the ore deposit with its extraction reserves of sub-floor collapse with face ore output under collapsed overlying rocks, and the formation of interchamber column pillars is carried out in the area of the treatment recess, in which the pressure on them does not exceed 30-35% of the total pressure acting on the interchamber pillars, calculated under the condition that they remain for the period of excavation of the chamber reserves of the panel, and the subsequent extraction of the interchamber column pillars is carried out until the pressure on them is reached 35 -45% of the total pressure acting on the interchamber pillars calculated on condition that they remain for the period of extraction of the chamber reserves of the panel, while the sub-floor collapse is lagging behind the chamber-pillar system at least one chamber filled with collapsed overlying rocks. 2. The method according to claim 1, characterized in that the development of the upper part is carried out with the installation of a flexible separating overlap on the soil of the worked out space, and the end production of ore under collapsed rocks is carried out under a flexible separating overlap.