RU2085739C1 - Method for mining thick steep coal seams - Google Patents

Abstract

FIELD: coal mining industry. SUBSTANCE: method implies cutting drifts, mounting of flexible roofing consisting of two parallel lines which are made up of cylindrical sections. Lines of roofing are connected to each other by rigid links, and placed upon them is metal net. Sections in each line are connected by flexible link at ends. Repositioning of roofing is effected according to extraction of coal from lower lying sub-levels, and it is dismantled in collecting drift. EFFECT: high efficiency. 4 dwg

Description

 The invention relates to the mining industry and can be used in the development in underground of powerful steep coal seams with the use of bypass lining and hydromechanics.

There is a method of developing powerful steep layers of sub-floor hydraulic breakdown with flexible overlap. The essence of the method consists in the extraction of coal from the excavation drifts with openings under the protection of flexible overlap mounted in one plane of the sub-floor. The disadvantage of this method is the large amount of preparatory work, the complexity of ventilation, there are cases of a rush of collapsed rocks bypassing flexible overlap on the lying side of the reservoir [1]
A known method for the development of powerful steep coal seams, including the accumulation and ventilation drifts, on the basis of the last installation of the drain floor, hydraulic breakdown of coal from the excavated floor drifts, the bypass of the floor as the underground floor is worked out,
The disadvantages of the method include the high complexity, rupture of the flexible floor when conducting treatment work and the rush of rocks into the treatment space [2]
The objective of the invention is to increase the efficiency of mining powerful steep coal seams.

 The stated problem is achieved in that the method of developing powerful steep coal seams with sub-floor hydraulic pumping is carried out in descending order from sub-floor excavation drifts under the protection of volume bypass overlapping and includes the accumulation and ventilation drifts. From the boundary of the extraction block to the slope of the ramp, a mounting chamber is carried out at the full thickness of the formation through a ventilation drift, where a volumetric flexible lowering overlap is installed, consisting of 2 branches of individual cylinders located by wiping near the soil and the roof of the formation and interconnected by a chain or cable in each branch, and the branches in the cross of the strike are connected by a profile for rigidity through a certain distance, a metal mesh is laid on top of the profile.

 Cylinders can be solid metal or assembled from separate rings of a special profile rigidly interconnected. In a longitudinal section, the cylinder is a trapezoid, the smaller base of which during installation is located on the soil of the mounting chamber.

 Installation of a volumetric flexible lowering floor is performed on the top ventilation drift and serves the entire term of mining the extraction block with subsequent dismantling on the accumulating drift for reuse, while reliably protecting the working face from a break in collapsed rocks, provides ventilation of the working face due to mine depression, and reduces operating losses coal, reduces labor intensity and increases productivity, significantly improves conditions and increases the safety of workers x in mining.

 Figure 1 presents the mining scheme of the extraction block in the plane of the reservoir; in FIG. 2 section aa (Fig. 1) and the sequence of mining excavation approach; in FIG. 3 section BB (Fig. 1); in FIG. 4 section bb (Fig. 1).

 The development of a powerful steep formation is carried out in the following sequence.

 The formation along the strike is divided into excavation sections, and the sections into excavation blocks. The excavation unit 1 from the field drifts is opened by transport 2 and ventilation 3 crosshairs. An accumulating drift 4 is carried out from the transport 2 crossover to the boundaries of the excavation section 4, and a ventilation drift 5 from the ventilation 3 crossover. Prior to the beginning of the preparatory and cleaning works, a slope 6, a slurry kiln 7, and a ventilation furnace 8 are carried out in the excavation block. A safety pillar is left between the excavation blocks 9. From the ramp 6 to the boundary of the extraction block 1, excavation sub-floor drifts 10 are carried out, which at the safety pillar 9 are knocked out by a split furnace 11. On the ventilation 5 drift in reverse the mounting chamber 12 is carried out at full reservoir power and a volumetric lowering cover 13 is mounted, consisting of 2 branches of cylinders 14 interconnected by the SVP-22 profile for rigid connection 15 and through guides 16, for flexibility, the cylinders along the strike are connected by a ship chain or cable 17 , over the profile 15, a metal mesh 18 is laid, which acts as a load distribution from collapsed rocks.

 Before the start of the treatment work in the extraction sub-floor 19, a backup excavation sub-floor 20 is cut, which is connected to the main one by a safety fault 21 and a split furnace 11. The hydraulic monitor 22 is installed on the sub-floor drift 10 and the treatment works begin. In process of testing sunset 23, the hydraulic monitor is moved to a new sunset, and the volumetric lowering cover under its own weight and the weight of the collapsed rocks is transferred to the soil of the excavated sub-floor drift. Underfloor drifts are fastened with wooden 24 or anchor support, pulp transportation is carried out through slurry gutters 25. Excavation of underfloor drifts is carried out by K-56 MG 26 combine.

 Airing of working faces is carried out due to mine depression, and preparatory faces by local ventilation fans 27.

 Coal mining in the block is carried out from the excavation sub-floor drifts in a descending order, the cleaning operations are carried out by hydro-hydraulic coal from the openings under the volumetric lowering floor, which smoothly transferring to the soil of the excavating drift as the waste treatment is completed.

 This method using volumetric lowering overlap will increase the efficiency of coal mining, the safety of mining due to the constant bypass of flexible overlap from one sub-floor to another, the cost of installation and dismantling will be reduced, there is no need for a second excavation sub-floor drift in each excavation sub-floor with a layer capacity 8-12 m. The volumetric lowering cover reliably protects the treatment space from the penetration of collapsed rocks, serves as an emergency exit and It functions as a ventilation drift.

Claims (1)

 A method of developing powerful steep coal seams, including accumulating and venting drifts, on the basis of the last installation of a flexible drainage floor, hydraulic breaking of coal from excavated floor drifts, bypassing the floor as the underlying floors are worked out, characterized in that the flexible floor is mounted in two parallel, connected through the hard ties of the branches on the soil of the upper ventilation drift and dismantle on the accumulator, while on top of the hard ties lay a metal mesh, and branches are assembled from cylindrical sections having a trapezoidal shape in longitudinal section, cylindrical sections are connected at the ends by a flexible connection.

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