RU2114389C1 - Method of blasting operations in gassy mines - Google Patents

Abstract

FIELD: mining industry. SUBSTANCE: part of the face area is separated by a shaft dam with labyrinth packing near the working bed, cut holes and advance hole are drilled for a more intensive liberation of methane, mine atmosphere is displaced by methane with monitoring of displaced flow by a gas analyzer, and after the composition of gas mixture incapable of burning and burnt is attained, cut hole charges of high amount and power are bursted. For attenuation of air shock waves a water-filled shaft dam of hoses freely hanging in working height is installed. EFFECT: enhanced efficiency of blasting operations in gassy (methane) mines. 5 dwg

Description

 The invention relates to the mining industry and is intended for mining in coal mines, dangerous for gas.

 There is a method of blasting in an oxygen-free (methane) environment by constructing a gas-tight jumper with a labyrinth near the mine soil in a dead end mine. After filling the isolated part of the production with methane and the formation of an environment incapable of burning and exploding, blast holes explode using powerful non-fuse explosives.

 The disadvantages of this method is the difficulty of industrial use with insufficiently intense methane emission and low blasting efficiency.

 The aim of the invention is to increase the efficiency of blasting.

 To achieve this goal, a method of blasting in mines when conducting gas-hazardous mine workings, including drilling, charging and jamming holes, installing an electric blast network, installing a gas-tight jumper with a labyrinth at the mine soil, expelling the mine atmosphere from the closed space, methane released their coal seams with an exit through the labyrinth and control of the displaced gas flow by the gas analyzer, culminating in the blasting of hole charges, additionally drill ahead of a borehole parallel to the boreholes and install a water filler jumper in the form of sleeves made of film materials filled with water and fixed at the excavation arch freely hanging in its height in parallel rows overlapping the cross section of the mine.

 In FIG. 1 and 2 show the layout of objects used to implement the method in the longitudinal and cross sections of the mine; in FIG. 3 is a diagram of the fastening of elastic plates for sealing a closed space; FIG. 4 is a diagram of a water filler jumper; FIG. 5 is a diagram of the suspension of the sleeves of a water-filling bulkhead with doubling of the sleeve in a bunch.

 To implement the method, a gas-tight jumper 1 with a labyrinth 2 and a gas analyzer 3 is placed in the mine working, drill holes 4 and a leading well 5 are drilled. plates 8 made of elastic materials (porous rubber) are fixed at one end along its perimeter, and the free ends of the elastic plates 8 are pressed against the surface of the walls, arch and soil of the excavation, while the elastic plates 8 are attached extend to elastic plates 9 made of fiberglass or equivalent materials, with a load capable of longitudinal bending. The water filling bridge is made in the form of a curtain made of vertical freely hanging sleeves 10 made of film materials filled with water and mounted on a pipe (or other support) 11 intersecting the cross section of the working.

 An example of the application of the method.

 With enhanced ventilation, bore holes are drilled and well 5 parallel to them, using a straight cut, a spiral cut or a Koroman cut. The bore holes are charged with 4 explosives, using powerful non-fuse explosives with high detonation ability, which excludes the burning of drill holes, they are jammed and the electric blast network is mounted.

 A water filler web is formed from polyethylene sleeves with a diameter of 40-60 mm, hanging the sleeves 10 filled with water on the pipe 11, fixed at the arch of the mine. Sleeves 10 are placed in two to three parallel rows intersecting the cross section of the mine. The first row is as close to the chest of the face.

 After the suspension of water-filled sleeves 10, stopping the ventilation of the wetted area, proceed to the assembly of the jumper 1, continuing intensive ventilation outside the jumper.

 For unimpeded transportation over the mine workings, the jumper is collapsible. A frame 6 of two halves is assembled and a jumper is installed 2.0-2.5 m from the bottom. Check the adherence to the working surface of the flexible elastic plates 8 of porous rubber, fixed around the perimeter of the frame 6, if necessary, moving (pushing or pushing) some of the plates 8 depending on the state of the surface of the working, then insert the knockout elements 7 of the central part of the jumper - sheets from plywood or foam board.

 The installation site of the knockout elements 7 are sealed with strips of microporous rubber, mounted on the end surface of the knockout elements 7 along their perimeter or on the surface of the frame 6 in contact with the ends of the inserted sheets or plates.

 In the last (from the bottom) section of the labyrinth 2, a gas analyzer sensor is installed for oxygen. With intensive ventilation of the face before the jumper, measurements of the gas stream leaving the maze continue. Methane released from the exposed surface and the leading well is collected at the arch of the closed bottomhole space, gradually displacing the mine atmosphere. At a content of 12 vol.% Oxygen, the gaseous medium is incapable of burning and exploding. For a guarantee, measurements are brought up to 8-10%, the gas analyzer is removed from the labyrinth and left for shelter. During this time, the oxygen content in the bottom hole decreases further. After additional verification of the explosive network produce an explosion.

 With an air shock wave, low-inertia knockout elements from the central part of the jumper will be knocked out (which ensures repeated use of the jumper), and the slaughter will be available for ventilation by continuing ventilation.

Claims (1)

 A method of blasting in mines when conducting gas-hazardous mine workings, including drilling, charging and jamming holes, installing an electric blast network, installing a gas-tight jumper with a labyrinth at the mine soil, displacing mine atmosphere from the bottomhole space with methane released from coal seams with exit through the labyrinth and control of the displaced gas stream by the gas analyzer, culminating in the blasting of blast holes, characterized in that they also drill a leading well and install poured into water filling bridge in the form of sleeves, of film material, filled with water and set at fixed output, hanging freely by its height parallel rows intersecting a cross section of excavation.

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