RU2425218C1 - Underground development method of series of thin steep deposits - Google Patents

Abstract

FIELD: mining. ^ SUBSTANCE: load-carrying flooring is built under thickness of dangerous rocks. Flooring has the type of grid consisting of series of wells drilled from lower wall to side wall of series of steep ore bodies inside which pre-stressed ropes are arranged. After tension of ropes, their ends are fixed on surface of walls of minings by means of pipes having L-shaped cutout. Wells are filled with curing mixtures. Development of deposits is performed after erection of flooring. ^ EFFECT: higher development safety of series of thin steep ore deposits. ^ 2 cl, 6 dwg

Description

The invention relates to the mining industry and can be used to develop powerful ore bodies. Tens and hundreds of meters of steeply falling deposits and ores are known in conditions in which it is necessary to prevent the breakthrough of water, quicksand and other fluids into the working space of the mine (for example, under the bottoms of quarries, ponds, the thickness of the flooded Quaternary deposits). With the consent of the occurrence of thin ore bodies lying under rocks that are prone to breakthroughs of liquid fluids, in some cases it is advisable to jointly develop them using technologies used on powerful strata or ore bodies.

A known method of developing powerful steeply falling deposits of weak ore (RF patent No. 22448448, E21C 41/22, publ. 2005.03.30). The method includes sinking ventilation and filling and boring loading gates, excavation of minerals oriented in crosswise direction by rhombic or ellipsoid shaped chambers, with displacement of the chambers of adjacent floors by half their width, with excavation of ore by blasting of wells and laying of mined-out space. Directly above the upper floor, a protective ceiling is constructed with a slope of 5-7 ° in the direction of the hanging side of the deposit. The width, the height of the chambers and the height of the chambers of the upper floor, the angle of inclination of the side walls of the chambers are determined from mathematical expressions based on a stable calculated span of the protective cover, the width of the loading unit and the angle of internal friction of the ore mass. After the construction of a protective overlap, the ore in the chamber is developed by explosions by wells in a clamped medium, and the next run is worked out after the laying of the next run. In unstable, prone to collapse ores slaughtering treatment chambers give a slope corresponding to the angle of repose of the ore mass. In ores with rock layers, the slope of the treatment chambers is given a slope corresponding to the angle of incidence of the ore deposit.

The disadvantage of this invention is the high risk of work under objects that are dangerous for breakthroughs of fluids, as due to the inevitable shrinkage of the filling material, as well as a possible under-deposit when filling the chambers with a filling, the deposit of filling material and covering ores and rocks with a violation of their waterproofing properties occurs, which can lead to to breakthrough fluids.

There is a method of layer mining buried diamondiferous placers with the presence in the contours of mine fields of cavities with diamondiferous ore (RF patent No. 2345219, Е21С 41/16, Е21С 19/02, publ. 2009.01.27). The method of layer-by-layer mining of buried diamond-bearing placers with the presence of cavities with diamond-bearing ore in the contours of mine fields includes mechanical mining of the upper layer by chambers, followed by working out of the pillars and installation of a flexible ceiling, and working out of the block caving system of the lower layer, including hollows with diamond-bearing ore. Flexible overlap is mounted only over the hollows with diamond ore. First, they mount a ceiling on the soil of the processed chambers simultaneously with their development. Then - on the basis of the worked support pillars with their simultaneous development, after which the flexible overlap of adjacent chambers and support pillars are connected to each other.

The disadvantage of this invention is the high risk of mining under objects that are dangerous for breakthroughs of fluids, since due to the collapse of the covering ores and rocks, their waterproofing properties are violated, which can lead to breakthroughs of fluids.

A known method of developing powerful steep coal seams (RF patent 2085739, E21C 41/18, publ. 1997.07.27).

The inventive method includes conducting drifts, installation of a flexible ceiling, consisting of two parallel branches made up of cylindrical sections, the ceiling branches are fastened together via rigid ties, on top of which a metal mesh is laid. Sections in each branch at the ends are connected by a flexible connection. Bypassing the overlap is carried out as the coal mining of the underlying floors, and dismantled on the accumulating drift.

The disadvantage of this invention is the high risk of work under objects that are dangerous for breakthroughs of fluids, since due to the collapse of the covering ores and rocks, their waterproofing properties are violated, which can lead to breakthroughs of fluids.

The technical result of the invention is to increase the safety of mining a suite of thin steeply falling ore deposits occurring under objects that are dangerous for fluid breakthroughs, the underworking of which is associated with the danger of fluid breakthrough into the working space of the mine.

The technical result is achieved by the fact that in the method of underground development of a suite of thin steeply falling ore deposits, including the excavation of preparatory and rifled mine workings, installation of an overlap consisting of parallel branches of cylindrical sections, mining of primary and secondary chambers within a mining field using drilling and blasting blasting , filling the spent spaces of the primary and secondary chambers with a tab, according to the invention, as cylindrical sections I use wells drilled from a hanging to a lying side field, in these wells was placed carrying ropes, which after fixing to walls generate create pretension and secured using clamps and rods. After mounting the ropes in them, the wells are filled with hardening mixtures, and the ropes are fixed at the wellhead using pipes fixed by rods. The pipes have a L-shaped cutout on the surface for the convenience of tensioning the ropes and fixing them to the surface of the mine working. The width of the L-shaped slit is selected from the condition of the need to place a rope of the corresponding diameter in it.

The application of the proposed method in comparison with the prototype allows to increase the safety of mining powerful steeply falling ore deposits lying under objects that are dangerous for breakthroughs of fluids into the working space of the mine. The stability of the protective rock stratum is ensured by reinforcement with steel ropes.

The technical essence of the invention is illustrated in figures 1-6.

Rope overlap erected after sinking from the haul-off drift 7 of the ventilation uprising 6 and drifts 2, the number of which is determined by the number of parallel low-power deposits. The drifts are connected by the orts 4, necessary for the construction of the rope overlap. Wells with a diameter of 100 mm are drilled from drifts into which steel ropes are then installed and fixed. The fastening of the ropes at the wellhead is carried out using pipes installed directly at the wellhead perpendicular to their axis. Pipes on the surface of the mine workings are fixed with bars. Moreover, the pipes have a L-shaped cutout on the surface, into which the end of the rope emerging from the well is inserted and fixed after tensioning with a clamp and an anchor. After their installation, the wells and the unit 4 are filled with a hardening mixture, which allows the waterproofing of the underlying ore mass from flooded overlying rocks. The distance between the ropes is determined depending on the conditions of their loading by known methods. The drift 2 in the hanging side is filled with a hardening mixture after the erection of the rope overlap. The remaining drifts 2 fill after the bookmark in the whole block. The number of chambers in the block is determined from the condition of ensuring the stability of the artificial pillar between the processed chambers.

Simultaneously with the construction of the cable-borne roof, preparatory cutting work is underway on the sinking of the drilling unit 1 and drifts 5.

Cutting of the ore mass is carried out by one funnel after the cutting of the cutting riser. Ore is discharged from the chamber by means of a vibroinstallation unit (type VVDR).

To ensure the release of all ore, the bottom is made inclined at an angle of 60 ° along the length of the chamber. This shape of the bottom ensures its stability during ore breaking in the chambers and when the filling array is exposed during further mining of the underlying chambers. The length of the chamber is determined by the stability of the rocks of the hanging side and is calculated by known methods. The distance between simultaneously processed chambers in the deposits is determined by calculation based on the conditions for ensuring the stability of interchamber ore or artificial pillars and can vary from 40 to 120 m. When working out parallel deposits, the chamber is first worked out in the lying side deposits, and then after filling the chamber with the tab - hanging. The cameras are filled with a bookmark from drift 2 through failures 3.

The fastening of the ropes on the surface of the workings is shown in Fig. 5 and Fig. 6. Directly at the wellhead 9, the pipe 10 is fixed using the rod 11, then a rope 8 is placed in a pre-made L-shaped cut-out 12, a preliminary tension is created in it and the end of the rope is fixed on the working surface with the help of the rod and clamp 13. The inner diameter of the pipe for securing the ropes should be from a safety condition of at least 10 rope diameters, which ensures reliable fastening of the ropes on the surface of the workings.

Claims (2)

1. The method of underground mining of a suite of thin steeply falling ore deposits, including the excavation of preparatory and rifled mine workings, installation of a slab consisting of parallel branches of cylindrical sections, mining of primary and secondary chambers using a drilling and blasting block, filling the mined-out primary space and secondary chambers with a bookmark, characterized in that for mounting the ceiling on contact with weakened rocks under the aquifers the drifts are drilled, parallel rows of wells are drilled from the drifts and used as overlap, and the wells are drilled from the lying to the hanging side of the field, inside which are placed load-bearing ropes, which after prestressing are fixed on the walls of the drifts, and then the wells and drifts of the hanging side are filled with hardening concrete mix. 2. The method according to claim 2, characterized in that the fastening of the ropes on the walls of the workings is carried out using pipe segments attached to the vertical surfaces of the workings using rod supports, and the pipes have L-shaped cutouts for accommodating ropes in them, which, after tensioning them fixed on the walls of the mine with the help of rods and clamps.

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