RU2532929C1 - Methods of mechanised steep bank excavation of medium power in bands down dip - Google Patents

Abstract

FIELD: mining.

SUBSTANCE: invention relates to mining, to mechanised steep bank excavation of medium power in bands down dip. The method comprises preparation of the extraction column and extraction band by mining. At the junction of the mounting chamber with coal chute the second mounting chamber is made, which workspace is supported by face-end support strutted between the roof and the layer soil. Each layer of the soil is imparted with the horizontal gradient of not less than the angle providing gravity handling of the chipped coal on the chutes. The multislice mining of coal is carried out using a swept cutter tool, made in the form of a horizontally oriented drum with cutters mounted on the sides of the front section of the chute. Supply of the cutting tool is carried out by moving the front section of the chute to bottom hole, its moving in the opposite direction is carried out by moving the front section of the chute towards the coal chute. The direction of the drum rotation of the cutting tool provides cutting coal from the bottom upwards. The chute flight is enlarged using spare chutes, and the second mounting chamber is elongated to the extent of mining the layers in the band. Removal of stabilising pillar is carried out using cutting actuating tools of the sections of the expanding shield overlap.

EFFECT: invention enables to improve the efficiency and safety of mining by organising gravity handling of chipped coal.

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Description

The invention relates to mining, in particular to the mechanized development of steeply falling coal seams of medium power with long columns along strike, taken out by strips along the dip, i.e. on the shield development system.

A known method for the development of steep and steeply inclined coal seams of medium power, including the preparation of the excavation column by transport and ventilation drifts, the preparation of the excavation strip by the conduct of slopes equipped with a carbon drain compartment, and the mounting chamber, installation of mechanized roof support sections in it, aggregated with an executive body, made in the form boom equipped with a horizontally mounted auger cutting body; mechanized excavation and transportation of coal along the face to the coal slope [1]. The disadvantages of this analogue are that when transporting chipped coal along the face, screw executive bodies of mechanized sections are used, and the performance of the working face is limited by the capacity for transporting one screw executive body; when pouring chipped coal from a ledge to a ledge, the dust content of the mine atmosphere sharply increases.

The closest analogue to the proposed technical solution, adopted as a prototype, is a method for developing a steep coal seam in strips along the dip, including preparing a excavation column by carrying out conveyor and ventilation drifts, preparing a excavation strip by conducting flank and near slopes along the fall line from the conveyor to the ventilation drift on both to the sides of the strip, holding the mounting chamber at the ventilation drift with the support pillars remaining, installing a sliding shield panel in it rytiya lining, the layers recess mechanized coal working face cutting body formed in a horizontally-oriented drum cutters, coal transportation along the face and airing stope due obscheshahtnoy depression. In this soil, each layer is biased towards one of the slopes. The pillars of coal remaining within the excavation strip are removed by the cutting executive bodies of the sections of the sliding shield panel. When removing the safety pillar from the conveyor drift, coal-hole wells are drilled in the alignment with each section [2].

The disadvantage of the prototype is that the coal is mined by the executive body of the combine, which has large dimensions that do not allow the development of steep layers of medium power. The left supporting pillars holding the shield sliding overlap will be negligible, therefore unable to perform their function. This drawback reduces the efficiency and safety of developing steep coal seams of medium power.

The aim of the invention is to increase the efficiency and safety of the development of steep coal seams with strips in the fall due to the organization of gravity transport of chipped coal along the face and the use of a remote system for feeding the cutting body to the face.

This goal is achieved by the fact that in the method of mechanized development of a steep coal seam of medium power with strips in the fall, including the preparation of the excavation column by conducting conveyor and ventilation drifts, the preparation of the excavation strip by conducting the flank and near slopes along the fall line from the conveyor to the ventilation drift on both sides of the strip, holding the mounting chamber at the ventilation drift with the support pillars remaining, mounting sections of the sliding shield cover of the lining in it, with a swept cutting body, a layer excavation of coal in the working face by a cutting body, made in the form of a horizontally oriented drum with incisors, giving the soil of each layer a slope towards one of the slopes, excavation of the pillars by the cutting executive bodies of the sections of the sliding shield panel, coal transport along the face and drilling coal-hole wells in alignment with each section of the shield sliding overlap when excavating a safety pillar, according to a technical solution for pairing the mounting chamber with coal with a launching ramp, a second mounting chamber is carried out, the working space of which is supported by a pair of supports supported between the roof and the soil of the formation, the soil of each layer is given a slope to the horizon of at least an angle that provides gravity transport of the beaten coal along the gutters, a cutting body made in the form of a horizontally oriented drum with cutters, set on the sides of the front section of the gutter, the supply of the cutting body is carried out by moving the front section of the gutter to the bottom, moving it in the opposite direction provides They are moved by moving the forward section of the trough towards the carbon slope, while the direction of rotation of the drum of the cutting organ ensures the cutting of coal from the bottom up, becoming troughs by increasing the spare troughs, and the second mounting chamber is extended as the layers are worked out in the strip.

The essence of the method of mechanized development of a steep coal seam of medium power with stripes in the fall is illustrated by schemes. Figure 1 shows the preparation of the excavation strip and the order of mining layers in the strip; figure 2 - arrangement of equipment in the face; figure 3 is the same (cross section).

A coal seam of medium power, lying, for example, vertically, is prepared for mining by a shield development system. Transport 1 and ventilation 2 drifts are carried out, between which a dredging strip is cut by flanking 3 and near 4 slopes along the dip line. At the interface of the dredging strip with the ventilation drift 2, a mounting chamber 5 is carried out with the support pillars left at the soil and the roof of the formation, on which sections of the shield sliding floor 6 are mounted, which are interconnected by flexible couplings or moving jacks. At the interface of the excavation strip with the flank slope 3, a second mounting chamber 7 is carried out, in which the mount of the interface 8 is mounted.

Coal breakdown is carried out by a cutting body made in the form of a horizontally oriented drum 9 with cutters mounted on a telescopic boom 10 with a drive 11 mounted on the sides of the forward section of the gutter 12. The support pillars at the roof and the soil of the bed are cut by arrow-shaped executive bodies 13 installed on each sections of the shield sliding floor 6.

In the inner space of the lining pair 8 lay a set of sections of the gutters. On the upper section of the gutters, the drive 11 of the cutting organ 9 is fixed. The coal is excavated in inclined layers. With the grippers 14 of the hydraulic pusher 15, installed at an angle to the horizontal, with the drive of the cutting body turned on, the upper section of the chute 12 is fed to the bottom. In this case, the coal is cut by moving the cutters from the bottom up. Due to the mass of the cutting body with its boom and drive, as well as due to the direction of rotation of the cutting body, the bottom of the trough 12 is pressed against the soil of the removable layer. Chipped coal, raised by rotation of the cutting body, enters the chute 12 and then by gravity is transported to the ramp 3.

As the gutter moves by the stroke of the pusher 15, the sides of the gutter are released from the jaws 14, the pusher is returned to its original position, the grips 14 are re-secured to the sides of the gutter 12 and the cycle of feeding the cutting body to the face is repeated.

After moving the bottom to the length of the gutter section, the next gutter section is docked to the first gutter, connecting them with a quick-disconnect connection, and coal extraction in the inclined layer is continued.

At the end of the excavation of the layer, the cutting body goes into the mounting chamber (when removing the first layers) or into the ramp 4; its drive is turned off, and the pusher 15 returns the cutting body to the mounting chamber 7 by reducing the stavage of the grooves 12 and storing the sections in the inner space of the support lining 8.

During the work to reduce the rate of gutters 12, miners of the working face enter the space under the shield sliding overlap and begin to cut the pillars at the roof and soil of the reservoir and control the shield sliding. For this, an arrow-shaped cutting organ 13 is used, suspended from the bottom of each section of the shield panel. First, the support pillar is cut from one side of the section by no more than the thickness of the layer and this side of the section is lowered; then another, etc.

Before starting the extraction of the next layer, the chute with the drive of the cutting body is lowered below the level of the spent layer by the power of the layer to be removed and then the cycle of operations in the layer is repeated.

As the layers are removed, the mounting chamber 7 is deepened, giving its soil a slope towards the slope 3 more than the angle of repose of crushed coal to ensure gravity transport.

When approaching the treatment work to the transport drift, the last inclined layer is removed, leaving the safety pillar 16 in the excavation strip, and the cutting body 9 and becoming the gutters 12 are dismantled. The remaining safety pillar 16 is removed by cutting swept bodies 13 sections 6 of the shield sliding floor, and the transport of broken coal is carried out by coal drain holes 17 drilled from the transport drift 1 in the alignment with each section of the shield sliding floor.

Thus, the supply of the cutting body to the face is carried out by firing up the gutter from the second mounting chamber, the loading of the broken coal and its transportation is carried out by gravity; neither one nor the other requires the constant presence of people in the face, which increases not only the efficiency, but also the safety of the treatment.

Information sources

1. A method of developing steeply inclined coal seams of medium power and thin. RF patent 2320872; claimed 10.04.2006, No. 2006111689, patent holder of the IUU SB RAS (analogue).

2. A method for developing a powerful steep coal seam in strips of dip. Patent No. 2462593 of the Russian Federation; claimed March 14, 2011, No. 2011109534, patent holder of the IUU SB RAS (prototype).

Claims (1)

Method of mechanized development of a steep coal seam of medium power with falling strips, including preparing a excavation column by carrying out conveyor and ventilation drifts, preparing a excavation strip by conducting flank and near slopes along the fall line from the conveyor to the ventilation drift on both sides of the strip, holding an installation chamber at the ventilation drift with leaving supporting pillars, installation of sections of the sliding shield cover of the lining equipped with an arrow-shaped cutting organ in it, to the layer the extraction of coal in the working face by a cutting body, made in the form of a horizontally oriented drum with incisors, giving the soil of each layer a slope towards one of the slopes, excavation of support pillars by the cutting executive bodies of the sections of the sliding shield cover, coal transport along the face and drilling of coal drain wells in in alignment with each section of the shield sliding floor when a safety pillar is excavated, characterized in that a second mounting chamber is carried out at the interface of the mounting chamber with the carbon slope The working space of which is supported by a support lining, sandwiched between the roof and the soil of the formation, the soil of each layer is given a slope to the horizon of at least an angle providing gravity transport of the beaten coal along the gutters, a cutting body made in the form of a horizontally oriented drum with cutters is installed on the sides of the advanced section gutters, the supply of the cutting body is carried out by moving the forward section of the gutter to the bottom, moving it in the opposite direction is provided by moving the forward section of the gutter to the side on the carbon slope, while the direction of rotation of the drum of the cutting body provides for the cutting of coal from the bottom up, becoming the troughs, increase the spare troughs, and the second mounting chamber is extended as the layers are worked out in the strip.

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