EA002431B1 - Method of working series of gentle ore deposits - Google Patents

Abstract

A method for working series of gentle ore deposits, which includes the preparation and advanced mining of the overlying series ore body by panels with panel reserves extracting by chambers, interchamber pillars forming and their further roof fall to cause the roof fall of top rocks and filling of chamber goaf with broken-down rocks, the mining of underlying series ore body by panels with panel reserves extracting by chambers, interchamber pillars forming and their further roof fall to cause the roof fall of top rocks and filling of chamber goaf with broken-down rocks with the difference that interchmber pillars under the working of the overlying ore body are to be formed in the actual mining zone where the pressure on them does not exceed by 30-35%the full pressure on the interchamber pillars calculated on condition of their saving during panel chamber reserves working and make the interchamber pillars extracting when the pressure on interchamber pillars ready to be extracted should reach 35-45% of the full pressure on the interchamber pillars calculated on condition of their saving during panel chamber reserves working, for all this the mining of each of underlying series ore body is made with lag what ensures the chamber reserves extracting and formed pillars extracting in the discharge zone, and the width of goaf is kept up within the width of the dome of natural equilibrium, formed in the broken-down rocks during the overlying ore body mining.

Description

The invention relates to the field of mining and can be used in underground mining of ores from deposits, representing a retinue of gently falling deposits, mainly of medium power, located at medium and large depths, chamber-pillar mining system. The main field of application is a retinue of deposits, the ore bodies of which are separated by rock layers with a thickness of up to 10 m.

There is a method of developing a suite of gently sloping deposits, including the excavation of preparatory workings dividing each deposit into extraction panels, advancing the extraction of minerals in the extraction panels of the overlying deposits and filling with collapsed rocks of the worked out space, subsequent mining of minerals in the extraction panels of the underlying deposits, moreover unloading (Mountain Encyclopedia vol. 3, Moscow, Soviet Encyclopedia, 1987, p. 425).

The disadvantage of this method is the high loss of ore in the pillars during the treatment of the excavation chamber-pillar development system.

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 inter-chamber pillars about exist until they reach a pressure of 35-45% of the total pressure acting on them, calculated provided that they are maintained for the period of extraction of the chamber reserves of the panel (EAPO patent No. 001183, cl. ⁶ E 21C 41/22, publ. 30.10.2000, bulletin EAPO No. 5-2000).

The disadvantage of this method is its inefficiency in the development of the formation of deposits.

The closest in technical essence and the achieved result is a method of developing a suite of gently dipping ore deposits, including preparing and advancing the development of an overlying ore body of the suite with panels to extract the reserves of the panel with cameras, forming inter-chamber pillar pillars and their subsequent collapse to initiate collapse of the overlying rocks and filling the collapsed rocks of the worked out rocks chamber spaces, development of underlying ore bodies of the suite with the extraction of panel reserves by cameras with excavation of interchambered pillar pillars and their subsequent collapse to initiate collapse of the overlying rocks and filling the caved space with the collapsed rocks (V. Imenitov. Underground mining processes in the development of ore deposits. M. "Nedra" 1984, pp. 194196, 326-332) .

The disadvantage of this method is the significant loss of ore in the interchamber pillars. Only 5-7% of ore reserves are extracted from interchamber pillars. With increasing depth of development and deterioration of mining conditions, losses will inevitably increase.

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

The resulting technical result is to reduce the complexity of mining operations while ensuring the completeness of the extraction of mineral reserves.

The specified technical result is achieved by the fact that in the known method of developing a suite of gently dipping ore deposits, which includes preparing and pre-empting the overlying ore body of the suite by panels with the extraction of panel reserves by chambers, the formation of interchamber column pillars and their subsequent collapse to initiate collapse of the overlying rocks and filling the collapsed rocks of the worked out chamber spaces, the development of underlying ore bodies of the suite with the extraction of the reserves of panels by cameras with the formation of m interchamber pillar pillars during the mining of the overlying ore body form in the zone of the treatment excavation, in which the pressure on them does not exceed 30-35% of the acting on the interchamber pillars full pressure, calculated under the condition of their preservation for the period of excavation of chamber reserves of the panel, and interchamber column pillars are extracted until reaching 35-45% of the total pressure acting on the interchamber pillars to be extracted, calculated on condition of their preservation for the period of excavation of the chamber reserves of the panel, while the development of each of the underlying ore bodies of the suite is lagging, ensuring the extraction of chamber reserves and the extraction of the formed pillars in the unloading zone, and the width of the worked out space is maintained within the width of the arch of natural equilibrium formed in the collapsed during development zhaschego ore rocks body.

Each of the signs of this set is necessary, and together they are sufficient to achieve the technical result. 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, is due to the fact that this zone is partially unloaded the edge of the deposit (face) and the formed interchamber pillars can have a smaller cross section compared to the calculated one.

Taking into account the factor of pressure change on interchamber pillars depending on the time of their standing, in the initial period, interchamber pillars do not experience pressure from the total weight of the overlying column of rocks (total pressure). Therefore, the extraction of interchamber pillars during the period when the pressure on them does not exceed 35-45% of the total pressure also allows reducing the cross section of the formed interchamber pillars in comparison with the calculated one.

The development of each of the underlying ore bodies of the formation with a lag, which ensures the extraction of chamber reserves and the extraction of pillars formed in the unloading zone, and the maintenance of the width of the worked out space within the width of the arch of natural equilibrium formed in the rocks collapsed during the development of the overlying ore body, can also reduce the cross-section of the pillars .

Reducing the cross-section of the pillars will increase the chamber reserves of the panel and, ultimately, reduce the complexity of mining operations and provide the necessary completeness of excavation.

A method of developing a suite of gently dipping ore deposits is as follows.

The retinue of gently dipping ore deposits is opened from the surface by the main and auxiliary vertical or inclined trunks, or a combination thereof. In the event that the retinue of sloping ore deposits is included in the mining allotment of an existing enterprise (mine, mine), previously passed opencast mines may be used.

The preparation of the mine field consists in its division into excavation sites. For dipping deposits, the most effective is the panel preparation, carried out by the sinking of panel drifts or orts.

The overlying gently dipping ore deposit by sinking panel drifts or unit vectors is divided into excavation panels. Preparatory workings pass through the ore mass. The development of the deposit can be carried out 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 of the overlying overburden can be determined from the condition of minimizing the costs of its development.

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.

The ore’s cleaning recess in the panel is driven by chambers with the formation of columnar inter-chamber pillars in the zone of the treatment recess, in which the pressure of the overlying rocks on the inter-chamber pillars is 30-35% of the total pressure acting on the inter-chamber pillars, calculated on condition that they remain for the period of excavation of the chamber chamber reserves. The formation of columnar interchamber pillars in this zone allows them to be formed with a reduced cross-section compared to the calculated one, and possibly with a reduced margin of safety, and thereby increase the active reserves of the chamber, which can be extracted using high-performance equipment. In addition, such pillars, when they are finely drilled, can be drilled only from the bottom of the chambers, which increases the safety of works for the extraction of interchamber pillars, since the equipment in this case is located in a safe area of the technological space.

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 for the whole thickness of the deposit. The formation of columnar inter-chamber pillars is carried out by fine-blasting breaking of the ore massif of the chamber with the use of cartridges or alluvial explosives. In the latter case, pneumatic chargers can be used to charge the holes. The delivery of broken ore is carried out using self-propelled equipment.

After the excavation of at least two chambers and the formation of two rows of pillar-shaped interchamber pillars, they begin to excavate the ore in the third chamber and extract the columnar interchamber pillars in the first chamber. In this case, the extraction of pillar-shaped interchamber pillars should be carried out during the period when the developing pressure of the overlying rocks on the extracted columnar interchamber 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 columnar inter-chamber pillars is carried out by small-bore or borehole blasting at one time 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 inter-chamber pillars as close as possible to the mine face.

By extracting the columnar inter-chamber pillars, the collapse of the overlying rocks is initiated and they fill the mined-out 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.

Each of the underlying deposits by the excavation of preparatory workings, for example, panel drifts or unit vectors, is also divided into excavation panels. The moving of the front of the treatment recess is carried out after the movement of the front of the cleaning recess of the overlying deposit with a lag, which ensures the extraction of chamber reserves and the extraction of the pillars formed in the discharge zone resulting from the overwork of the deposit.

The ore cleaning recess in the panel is conducted by chambers with the formation of columnar inter-chamber pillars. The formation of pillar-shaped interchamber pillars in the unloading zone allows them to be formed with a reduced cross-section compared to the calculated one, and possibly with a reduced margin of safety, and thereby increase the active reserves of the chamber, which can be extracted using high-performance equipment.

Ore extraction in the chambers is also carried out using self-propelled drilling rigs and delivery vehicles with soil-penetrating, ceiling-mounted or continuous slaughter for the entire thickness of the deposit. The formation of columnar inter-chamber pillars is carried out by fine-blasting breaking of the ore massif of the chamber using cartridge or placer explosives. In the latter case, pneumatic chargers can be used to charge the holes. The delivery of broken ore is carried out using self-propelled equipment.

The width of the worked out space is maintained within the limits of the width of the arch of natural equilibrium formed in the rocks collapsed during the development of the overlying ore body. To do this, after excavating at least two chambers and forming two rows of pillar-shaped interchamber pillars, they begin to excavate the ore in the third chamber and extract the columnar interchamber pillars in the first chamber.

By extracting the columnar inter-chamber pillars, the collapse of the overlying rocks is initiated and they fill the mined-out 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.

Claims (1)

CLAIM A method of developing a suite of shallow dipping ore deposits, including preparing and advancing the development of an overlying ore body of the suite by panels with the extraction of panel reserves by chambers, forming inter-chamber pillar pillars and their subsequent collapse to initiate collapse of the overlying rocks and filling with the fallen rocks of the mined chamber space, development of underlying ore bodies from the suite extraction of panels by cameras with the formation of interchamber column pillars and their subsequent collapse for causes collapse of overlying rocks and filling with collapsed rocks of the mined-out chamber space, characterized in that the interchamber column pillars during mining of the overlying ore body are formed in the zone of the treatment excavation, in which the pressure on them does not exceed 30-35% of the total pressure acting on the interchamber pillars, calculated under condition of their preservation for the period of extraction of chamber reserves of the panel, and interchamber column pillars are extracted until pressure is reached on interchamber column pillars 35-45% of the total pressure acting on the interchamber pillars, calculated on condition of their preservation for the period of extraction of the chamber reserves of the panel, while the development of each of the underlying ore bodies of the formation is lagging, ensuring the extraction of chamber reserves and the extraction of formed pillars in the unloading zone, and the width of the worked out space is maintained within the width of the arch of natural equilibrium formed in the rocks collapsed during the development of the overlying ore body.