RU2732166C1 - Roof control method - Google Patents

Abstract

FIELD: mining.

SUBSTANCE: invention relates to mining industry, namely, to underground development of deposits, and can be used for elimination of roof hang at the boundaries of extraction section. Method includes drilling of wells into rocks of mine working roof, their sealing and injection of liquid into them in hydraulic fracturing mode. Wells are drilled in one plane in direction of their approach to intersection. Wells are sealed and bled by injected fluid before formation of tensile stress field in well drilling plane, then, pressure is increased until rock breaks with occurrence of increasing crack till it reaches the working surface, from which wells are drilled. Fluid is injected through elastic sleeves pressed by pressure to walls of wells.

EFFECT: invention increases efficiency of the method of controlling roofing.

1 cl, 1 dwg

Description

The technical solution relates to the mining industry, namely to underground mining, and can be used to eliminate the hanging of the roof at the boundaries of the excavation area.

A known method of controlling a difficult-to-break roof according to ed. USSR No. 825962, class E21C 41/04, publ. 30.04.1981, bul. No. 16. It includes drilling wells into the rocks of a difficult-to-break roof, sealing wells and injecting fluid into wells before hydraulic fracturing. In the rocks of the hard-to-break roof, slots are cut from the inside of each well, each slot is sealed, and fluid is injected. Liquid injection is carried out sequentially, starting from the slot on the wellhead side to the slot on the bottomhole side, performing layer-by-layer hydraulic fracturing.

Common to the analogue with the proposed method is drilling wells into the roof rocks, sealing wells and pumping liquid into the wells before hydraulic fracturing.

In this method, the roof is stratified by a plurality of cracks formed by hydraulic fracturing of the rock in planes, the orientations of which are set by the preliminary creation of initiating slots. For the formation of each crack, it is required to perform operations to create a separate initiating slot, seal it, supply an injection system to it, and supply a liquid. All this leads to a relatively high complexity of implementation and, as a consequence, low efficiency of the method.

The closest in technical essence and a set of essential features is the method of roof control in the development of coal seams according to the RF patent №1216345, class. E21C 41/04, publ. 03/07/1986, bul. No. 9. It includes drilling wells into the zone of tensile stress concentration located above the support at the boundary of the extraction pillar, creating embryonic cracks, sealing wells and injecting fluid into them in the hydraulic fracturing mode. The embryonic gap is created in a plane passing through the cutting edge of the support with an inclination of 50-80 ° to the layer of roof rocks, and the height Z from the outcrop of the roof rocks to the point of inception of the embryonic gap is determined from the expression

where h _T is the normal thickness of the immediate fractured roof, m;

m is the extracted layer thickness, m;

K _p - coefficient of rock loosening.

Common to the prototype with the proposed method is drilling wells into the roof rocks, sealing wells and injecting fluid into them in a hydraulic fracturing mode.

An indispensable condition for the successful implementation of this method is the production of cut-off cracks, the orientation of which is set by the nucleation gap developed by injecting a fluid into it under pressure in the hydraulic fracturing mode. At the same time, according to the results of numerous studies, fluid in the rock mass moves along the path of least resistance, forming tortuous channels, enters the plane of weakening (a plane with relatively weak adhesion of rock layers) and then moves along them in the mode of hydraulic dissection. This leads to a relatively low probability of the formation of solid cutoff cracks of significant size in the plane set without taking into account the structure of the rock mass. In addition, the method does not provide for the creation of a tensile stress field with a given orientation by drilling a plurality of wells in one plane with the subsequent expansion of their walls, as well as using the wells as guiding the front of hydraulic fracturing of rocks. As a result, the probability of the roof collapsing into the goaf is relatively small. All this determines the relatively low efficiency of the method.

The problem to be solved consists in increasing the efficiency of the method by creating a field of tensile stresses in the required plane by drilling approaching wells in it, the walls of which are bursting with the pressure of the injected fluid.

The problem is solved by the fact that in the method for controlling the roof, including drilling wells into the rock of the working roof, sealing them and injecting liquid into them in the hydraulic fracturing mode, according to the technical solution, the wells are drilled in the same plane in the direction of their convergence to the intersection, the wells are sealed and burst with the injected liquid until the tensile stress fields appear in the well drilling plane, then the pressure is increased until the rock breaks with the appearance of an increasing crack until it emerges on the surface of the working from which the wells were drilled.

This technical solution implements the idea of creating an artificial field of tensile stresses in the rock mass, providing the forced separation of the roof from the rock mass in a given plane. This is achieved by summing up the forces of the expansion of the walls of all wells and the pressure of the fluid on the surface of the cracks that arise and grow as a result of the fracture of the rock mass, as well as weakening the adhesion strength of the rock by the wells and the mentioned cracks in the specified plane. Drilling wells in one plane of fracture of the rock mass provides after the expansion of their walls a field of tensile stresses in the specified plane and, therefore, sets the orientation of the emerging cracks. Drilling wells in the direction of their convergence to the intersection provide the place where the rock mass begins to fracture. According to the research results, hydraulic fracturing of the rock starts from the zone of the smallest distance between the wells (from the zone of their greatest mutual influence). Note that the wells are supposed to be drilled at different angles and with the possibility of their mutual intersection. The spacing of the walls of the wells with the injected fluid ensures the combination of the operations of impacting the rock mass through the walls of the wells and its hydraulic fracturing in a given plane (in the plane of the wells). An increase in pressure to rupture leads to the formation of a crack. As a result, the efficiency of the method increases due to the creation of a tensile stress field in the required plane by drilling approaching wells in it, the walls of which are burst with the pressure of the injected fluid.

It is advisable to inject the liquid through elastic sleeves, pressed by its pressure to the walls of the wells. This eliminates the ingress of liquid into random natural fractures in the borehole walls with their subsequent development in arbitrary planes, which increases the reliability of roof collapse control and, therefore, increases the efficiency of the method.

The essence of the technical solution is illustrated by an example of a specific implementation of the roof control method and a drawing, which shows the simplest diagram of the implementation of the method in a section along a given fracture plane of the rock mass.

Wells 2 are drilled into the roof rocks of the working in one plane 1 (see drawing) in the direction of their convergence to the intersection. Then the wells 2 are sealed and their walls are burst with the injected fluid, from which a field of tensile stresses arises in the plane of the drilled wells 2, which are concentrated in the zones of the closest approach of the wells 2. After that, the pressure of the injected fluid is increased until the rock breaks. As a result, in the zone of stress concentration (in the zone of the closest approach of wells 2), an initial fracture 3 appears (hereinafter referred to as fracture 3), which, under the action of the pressure of the injected fluid, increases in size. It is possible to supply the injected fluid to the zone of the beginning of the fracture of the rock through elastic sleeves 4 (hereinafter referred to as sleeves 4), pressed by its pressure to the walls of wells 2. The boundary 5 of the fracture 3 moves between wells 2 until it reaches a free surface, for example, the surface of a mine 6, from which wells were drilled 2. When the boundary 5 of the fracture 3 emerges on the free surface, further growth of the fracture 3 stops due to the pressure drop in the injected fluid. To inject liquid into wells 2, you can use a main pipe 7 with branches in the form of pipes 8 inserted into sleeves 4. In this case, sleeves 4 can be fixed on pipes 8, for example, by compression rings 9, from which, when liquid is injected into them, wells 2 are sealed To create the required force of expansion of the walls of the wells 2 into free from pipes. 8 ends of sleeves 4 can be inserted into tubes 10 with valves 11 adjustable to a given pressure. In this case, the ends of the sleeves 4 can be fixed on the tubes 10 with crimping rings 12. The operations that implement the scheme shown in the drawing can be repeated many times until the roof collapses into the goaf.

The method is supposed to be used mainly to increase the efficiency of shallow coal seams mining by mechanized complexes with the collapse of the roof into the goaf. The impact on the roof is carried out in places where the permissible load on the powered support is exceeded.

Claims (2)

1. A method for controlling the roof, including drilling wells into the formation roof rocks, sealing them and injecting liquid into them in the hydraulic fracturing mode, characterized in that the wells are drilled in the same plane in the direction of their convergence to the intersection, the wells are sealed and burst with the injected liquid until tensile stress fields in the well drilling plane, then the pressure is increased to rupture of the rock with the appearance of an increasing crack until it reaches the surface of the working from which the wells were drilled. 2. The method according to claim 1, characterized in that the liquid is injected through elastic sleeves pressed against the walls of the wells by pressure.

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