EA014007B1 - Method of damp proof bulkhead erection in underground working - Google Patents

Abstract

The invention concerns mining engineering and may be used for isolation of underground working watered ground from a mining zone. The proposed method of drilling-and-blasting damp-proof bulkhead erection in an underground working allows improving of damp-proof properties of drilling-and-blasting rock bulkhead and thereby improving of underground work safety in difficult hydrogeological conditions. The assigned objective is accomplished in the following manner. The method of drilling-and-blasting rock bulkhead reaction by roof collapse, including two-stages formation of embankment by blasting of two sections of roof with reservation between them of rock mass in the shape of inverse trapezia, provides for forming from the inflow side an embankment which fully blocks the working. From the side opposite to the inflow a waterproof rubber-fabric membrane, whose edges are hermetically and nohermetically fixed on the bottom, walls and roof of the working, is put on the embankment material; the rubber-fabric membrane is covered with a layer of retaining lump rock by a pinpoint blast of the second section of the roof. The waterproof rubber-fabric membrane area and solidity, width of zone of its contact to the bottom, roof and walls of the working, height, volume and size of embankment lumps and retaining lump rock layer covering the rubber-fabric membrane are calculated depending on the roof rock properties, expected shifts of embankment wall covered with the rubber-fabric membrane and possible hydrostatic head.

Description

The invention relates to the mining industry and can be used to isolate a flooded section of an underground mine from a mining zone.

A known method of constructing a waterproofing lintel from standard waterproofing elements located along the output circuit and secured by hardening material. The disadvantage of this method is the use of expensive waterproofing elements, such as tubing [1].

There is also known a method of erecting a stowing rock lintel in a mine using a blasting method, including the construction of a mound of a lintel by collapsing the roof with the formation of a bearing part, a filter layer and leaving the rock mass in the form of an inverse trapezoid between the collapsed sections of the roof [2]. This method does not provide reliable waterproofing of the mine, requires a long time for the formation of a waterproofing layer and is intended mainly for carrying out hydro-laying works.

The objective of the invention is to increase the insulating properties of the waterproofing lintel and the safety of mining.

The problem is achieved in that in the method of erecting a waterproofing lintel in an underground mine, including the collapse of the roof and the formation of two embankments that completely overlap the cross section of the underground mine, oriented by the explosion of the roof section, oriented in the direction of the water influx, form an embankment completely overlapping the excavation from the side of the water inflow, onto the embankment material on the opposite side of the water inflow, a waterproof rubber-fabric membrane is laid, the edges of which are tightly fixed or non-hermetic It is natural on the soil, walls and roof of the mine, and then the rubber-fabric membrane is covered with a layer of retaining lumpy rock, while the area and strength of the rubber-fabric membrane, the width of the strip of its contact with the sole, the roof and the walls of the mine, the height, volume and size of the pieces of the embankment and the covering rubber-fabric membrane layers of retaining lumpy rock is calculated depending on the rock properties of the roof, retaining lumpy rock, expected displacements of the embankment wall overlapped by the rubber-fabric membrane and possible hydrostatic of pressure.

Preferably, the rubber-fabric membrane is covered by mechanical or hydraulic laying with lumpy rock or a hardening composition, or oriented against the direction of water inflow by undermining the second section of the roof, a distance calculated from the condition of water tightness and strength left between the collapsed sections of the trapezoidal rock mass.

The figure shows a waterproofing lintel in a vertical section along the longitudinal axis of the underground mine 1. It includes sections of the collapse of the roof 2 and 3, rock mass 4, embankment 5, rubber-fabric membrane 6, the retaining layer of rock 7, the roof of the underground mine 8.

The essence of the proposed method for the construction of waterproofing lintels in underground workings is illustrated by the following examples.

Example 1

For the operational construction of a waterproofing lintel, not designed for a long service period, at the first stage, drilled holes 2 and 3 are drilled in the roof of the irrigated underground mine 1 at the collapse of the roof and charges of explosive are laid according to the scheme providing rock breaking in the direction of water inflow for the collapse of the roof 2 and against the direction of the water inflow for the roof collapse section 3. The distance between the roof collapse sections 2 and 3 is calculated depending on the properties of the roof rocks from the condition of sufficient water permeability and strength of rock mass 4, left in the form of an inverted trapezoid in the roof of the underground mine 1. 3 and the distance between the sections of the collapse of the roof 2 and 3 take the base of the trapezoidal rock mass 4, located on the roof line of the underground mine 1. Explosion controls are guarded to the water inflow is part of the underground mine 1. Then a directed breaking of the rock is carried out by an explosion at the area of the collapse of the roof 2 and, thereby, an embankment 5 is formed that completely covers the cross section of the subway 1. The waterproofing rubber-fabric membrane 6 is laid on the material of the embankment 5 from the side opposite to the water inflow, the base of which is a strong polyamide fabric, the edges of the rubber-fabric membrane are fixed at individual points along the perimeter of the underground mine 1 by mechanical means: driving dowels into the prepared holes using metal and rubber washers to prevent damage to the rubber membrane. In this case, the rubber-fabric membrane on the embankment 5 is laid freely so that in the event of displacement due to compaction of the walls of the embankment 5 due to compaction with the covered rubber-fabric membrane 6 during the breaking of the rock in the area of the collapse of the roof 3, its loose central part could move without deforming or damaging it. The area and strength of the rubber-fabric membrane 6, the width of the strip of its contact with the sole, roof and walls of the mine are calculated depending on the expected displacements of the overlapping rubber-fabric membrane 6 of the wall of the embankment 5 and the possible hydrostatic pressure on the rubber-fabric membrane 6. stage directed explosion section of the collapse of the roof 3 cover the rubber fabric membrane 6 with a retaining layer of rock 7 in the form of pieces of different particle size distribution above the roof 8 underground generating 1. The volume of 1 014 007 and You are a cell retaining layer 7 rock is calculated based on the expected hydrostatic head acting on the rubberized membrane 6, and physico-mechanical properties of the rocks of the roof 1 underground excavation.

Example 2

To build a waterproofing lintel, designed for a long service life, at the first stage in the roof of an irrigated underground mine 1, drill holes in the roof collapse section 2 and lay explosive charges according to a scheme that ensures rock breaking of the roof collapse section 2 in the direction of water inflow. Explosion controls are brought to the underground mine part protected from the water inflow 1. Then, a rock is blasted in an explosion at the collapse section of the roof 2 and, thereby, an embankment 5 is formed that completely covers the cross section of the underground excavation 1. On the side of the embankment 5, from the side opposite to the water inflow, described in the previous example, a waterproof rubber-fabric membrane 6, the edges of which are fixed on the soil, walls and roof of the mine. To this end, around the perimeter of the underground mine 1, to ensure tightness of the contact of the edges of the rubber-fabric membrane with the walls, roof and soil of the underground mine, a hardening polymer-cement (cement) mortar is applied and mechanically, screw or anchor, using a perforated, steel tape (flexible, resistant to aggressive effects) profile) for reliable pressing of the edges of the rubber-fabric membrane 6 between the attachment points, tightly fasten through a layer of not yet hardened polymer-cement og (cement mortar) of the edges of the rubber-fabric membrane 6 along the perimeter of the underground mine 1. The method of laying the rubber-fabric membrane and determine its parameters are similar to those described in the previous example. At the second stage, by means of mechanical laying, the rubber-fabric membrane 6 is covered with a retaining layer of rock 7 in the form of pieces of different particle size distribution under the roof 8 of underground mine 1. The volume of the retaining layer of rock 7 is calculated depending on the expected hydrostatic pressure acting on the rubber-fabric membrane 6, physico-mechanical parameters the retaining layer of the backfill rock 7 and the roof rocks (affecting the depth of the development of cracks in the roof in the direction of water inflow when the roof collapse section 2 is undermined).

Instead of a rubber-fabric membrane in the claimed method, another material can be used with sufficient strength and elasticity, for example, thermoplastic elastomers, various kinds of reinforced films, etc.

The improvement of waterproofing properties in the claimed technical solution is achieved through the use of a durable waterproof rubber-fabric membrane, tightly pressing the retaining layer of the edges of the rubber-fabric membrane to the walls, soil and partially the roof of the underground mine 1, as well as by sealing the contact of the edges of the rubber-fabric membrane.

Thus, the proposed method of erecting a waterproofing lintel in an underground mine can be repeatedly used in mining and in construction. It allows you to increase the waterproofing properties of the rock lintel and the safety of underground work in difficult hydrogeological conditions.

Claims (3)

CLAIM 1. A method of erecting a waterproofing lintel in an underground mine, including roof collapse and the formation of two embankments that completely overlap the cross section of the underground mine, characterized in that a roof section, oriented in the direction of the water inflow, forms a mound completely covering the excavation from the side of the water inflow, onto the embankment material with a waterproof rubber-fabric membrane is laid on the opposite side of the water inflow, the edges of which are fixed hermetically or leaky on the soil, walls kach and the roof of the mine, and then cover the waterproof rubber-fabric membrane with a layer of retaining lumpy rock, the area and strength of the waterproof rubber-fabric membrane, the width of the strip of its contact with the sole, the roof and the walls of the mine, the height, volume and size of the pieces of the embankment and the waterproof rubber-fabric membrane covering the layer retaining lumpy rock is calculated depending on the properties of the roofing rocks, the expected displacements of the mound wall and the overlapping waterproof rubber-fabric membrane possible hydrostatic pressure. 2. The method according to claim 1, characterized in that the waterproof rubber-fabric membrane is covered by mechanical or hydraulic laying with lumpy rock or a hardening composition. 3. The method according to claim 1, characterized in that the waterproof rubber-fabric membrane is covered with an anti-direction of water influx undermining the second section of the roof, a distance calculated from the condition of the waterproofness and strength left between the collapsed sections of the trapezoidal rock mass.