SU1016515A1 - Method of working thin gently-sloping gas-laden gas-hazardous coal beds - Google Patents

Abstract

1. Method of developing FLAT THIN LAYERS bearing coal HAZARDOUS dust comprising the mine floor division into blocks holding the central, intermediate and inclined flank workings excavation reservoir, drifts, mining ventilation through ventilation flank wellbore and testing of pillars in the central unit inclined workings, characterized in that, in order to increase safety of work and improve working conditions due to the complete isolation of ventilation jets serving cleaning workings, tilting jets. servicing preparatory workings, additional flank air supply wells are conducted to the lower boundary of the block, at the upper boundary of the block intermediate inclined workings are connected by main drifts only with central inclined workings, the upper and lower reservoir excavation drifts between the flank and intermediate inclined workings suppress, airing the preparatory workings in the preparation period is carried out through the flank inclined workings, and the cleaning workings - through the central and other intermittent inclined workings, and during the period of working out of the column between the flank and intermediate workings, the clearing workings are aired through the flank inclined workings. 2. The method according to claim 1, characterized in that the ventilation wells are conducted at the lower boundary of the block, they are interconnected with each other by the main transport drift, where, at intermediate inclined workings, they are used to build explosion-proof insulating bridges at intermediate inclined workings and ventilation along sloping workings to the lower boundary of the block. 05 JV

Description

FIELD OF THE INVENTION The invention relates to the mining industry and is intended for the development of thin flat gas-bearing coal seams hazardous in dust. The known method of developing flat coal seams 1. There is also known a method of developing thin flat gas-bearing coal seams hazardous in dust, including dividing a mine floor into blocks, conducting central, flanking and intermediate inclined workings, excavating bed shchtrekov, airing mine workings through flank ventilation wells and working out the pillars in the block to the central inclined workings 2. However, the known methods are characterized by insufficient safety of work. The aim of the invention is to increase the safety of work and improve working conditions by completely isolating the ventilation jets serving the cleaning workings from the ventilation streams serving the preparation of the working. The goal is achieved by the fact that according to the method of developing thin flat gas-bearing coal seams hazardous in dust, including dividing a mine floor into blocks, conducting central, flanking and intermediate inclined workings, excavating bed drifts, airing mine workings through flank ventilation wells and working off the columns in the block to the central inclined workings, to the lower boundary of the block, additional flank air supply wells are conducted, at the upper boundary of the block intermediate slope The main workings are connected with main drifts only with central inclined workings, the upper and lower reservoir excavation drifts between the flank and intermediate inclined workings are repaired, the preparatory workings are ventilated during the preparation period through the flank inclined workings, and the workings of the clearing workings - through the central and intermediate inclined workings, moreover, in the drive of working the post between the flank and intermediate workings, the cleaning workings are aired through inclined workings. Vent holes are conducted at the lower boundary of the block, they are interconnected by a main transport drift, at which, at intermediate inclined workings, blast resistant insulating bridges are built on the side of flanking inclined workings, and the ventilation is carried out through inclined workings to the lower boundary of the block. The method is carried out as follows. With the proposed method of mining a thin flat gas-bearing formation dangerous for dust, central, flank and intermediate inclined workings are carried out in the center of the block. In the first variant, in order to carry out upward movement of air jets emanating from the bottom of the air, intermediate inclined openings are conducted from top to bottom under the developed space and are connected at the upper boundary of the block with central inclined openings by two field air supply and air discharge pins. In the second case, in order to carry out the downward movement of the air jets, the intermediate workings are carried out before the start of the cleaning works and are connected to the central inclined workings of the main transport level at the lower boundary of the block. For formations with a dip angle of more than 18 °, for which there are no civilian, cable and ground roads, three inclined workings are conducted in the center of the block. Mining operations are carried out in two periods. In the first period of time, the preparation of the excavation section is carried out, which includes carrying out transport excavation drifts for the entire length of the wing and ventilation drifts to the excavated space in the wing sections of the block between the flank workings and intermediate inclined workings. At the same time, mining above the located excavation sections of the pillars between the intermediate and central inclined workings is carried out. During this period, the central and intermediate inclined workings serve, both in the ventilation and transport relation, only clearing faces, and the flanking inclined workings - only preparatory. In turn, the central inclined openings service the central shafts of the mine, which are conducted in close proximity to this unit under development or are removed from it, connected to the central inclined openings of the timberings. Flanged openings are served by flank block air supply and ventilation holes (shafts). As a result, the maintenance of cleaning and preparatory work is carried out not only by independent inclined and horizontal workings, as in the prototype, but also by independent vertical workings. People, materials and equipment in the preparatory faces are delivered along flank wells and inclined flank workings. The rock and coal from the excavation is discharged separately or simultaneously in the form of rock mass along inclined flanking openings with the help of conveyors, traction winches or other means of transport, and then through the ventilation flanking trunk to the surface. In the second variant, the rock and coal can be transported from the flank inclined openings along the main transport drift to the central lifting shaft. The flanking wells or flank trunks will equip the air supply with a two-stand lift, the ventilation air receptacle with a single-stand and one- or two-step lift. The development of the pillars is carried out in the direction of the central inclined workings. Airing of the excavation sites is carried out by diluting the hazards at their sources during the downward ventilation of the clearing hole. The outgoing air stream from the lavas is directed to intermediate workings. The sections of the excavation shchrek between the central and intermediate inclined workings are supported behind the lavas and are used for the second time as ventilating when mining the underlying column. Before the beginning of the second mining period, the excavation ventilation slides, passed through the extension to the developed space in the block sections between the flank and intermediate workings, are connected to the sections of the excavation slits located between the central and intermediate workings. Transport shchtreki connected with the platform of the central inclined workings, after which begin the working of the underlying column on shchtreki and between the flank and intermediate inclined workings. Outgoing streams from lavas during this period of time are directed to flank inclined workings. During the second mining period, the excavation shpreki were not carried out. After the lavas completed their work on the sections of the pillars located between the flanking and intermediate workings, at these sites, the transport shredders, which were previously supported behind the lavas, were dragged and are in the intermediate workings. Then the work cycle is repeated. The isolation of the ventilation jets serving the cleaning work from the ventilation jets serving the preparatory work is due to the fact that, in the presence of air penetrating flank and central shafts, the upper main ventilation shields are carried out, in the first embodiment, only for connecting intermediate workings with central, and in the second variant they are not carried out at all, as a result of which there is no ventilation link between the treatment group and the group of preparatory faces at the upper horizon without jByeT. The excavation shchreks are dragged in the areas between the flank and intermediate inclined workings, isolated from each other, and the excavation shchrek is carried out only during the period when outgoing lavas are discharged to the intermediate inclined workings, due to which ventilation at the level of management of preparatory and no cleaning works are established between the group of cleaning and the group of preparatory faces. Additional flank air supply trunks are conducted, as a result of which the need for basic shchtrekov is no longer required in the first embodiment, and the ventilation link between cleaning groups and preparatory works is not established on the lower limit of the block. In the second variant, a shatter-resistant jumper is installed on the lower main shield. The strength of the jumper is calculated from the conditions so that it is not destroyed by the shock wave in the event of a gas and dust explosion. If the coal and rock from the preparatory work is directed along the main shaft to the central trunk, then in the bridge the pipe for the bypass of the pulp during free-flow hydrotransport of the rock and coal obtained during the preparatory work from the flank inclined workings along the main transport bridge to the central one is embedded. trunks. During pneumatic transport, the pipe is passed through a jumper, and when a conveyor belt is installed, it is a blast-resistant sluice device. At free-flow hydrotransport near the flanking inclined workings, a crushing plant is installed, and in the region of the central shaft - a dehydrator. Dehydrated mass serves skip to the surface. At the Brive-resistant web, a bypass excavation consists of three sections located at a right angle to each other. In each of these workings, slots with doors are installed in such a way that the total aerodynamic resistance of all these doors exceeds the resistance of the insulating bridge to a possible shock wave in the event of an emergency. Thus, a message is established between the isolated parts of the block. Airing of the dead-end parts of the main lower gateway, located between the flank and intermediate workings, is carried out with the help of air vent pipes, which are led out to the ventilation shafts. The proposed method can be applied on deep shchakht, since the central inclined workings are unloaded with discharge lavas prior to the start of cleaning works, the flank ones are worked out with still unformed temporary bearing pressure, and the intermediate workings either periodically quench by sections, or are carried out under the worked out space. The proposed method allows to eliminate the ventilation link between the groups of cleaning and preparatory faces in normal operation and in emergency situations; maintenance of cleaning and preparatory breakdowns should be made not only by independent inclined and horizontal, but also by independent vertical workings, which increases the transport capacity, allows it to isolate and specialize, switch, for example, to the conveyor method of rock delivery, and also completely isolate the airing all cleaning and preparatory faces, improve the reliability of ventilation of the faces, facilitate the management of ventilation flows, improve the reliability of technological chains th; improve the working conditions of workers; to significantly increase the safety of work, especially during an emergency situation.

Claims (2)

1. METHOD FOR THE DEVELOPMENT OF THIN GANFLEEP GAS-BEARING COAL STORES DANGEROUS BY DUST, including dividing the mine field into blocks, conducting central, flank and intermediate inclined workings, excavation strata, drifts, ventilating the mine workings through the flanking ventilation wells in the central block and working out the pillars workings, characterized in that, in order to increase the safety of work and improve working conditions by completely isolating the ventilation jets serving the treatment workings from ventilation Of the jets serving the preparatory workings, additional flank air supply wells are carried out to the lower boundary of the block, at the upper boundary of the block, the intermediate inclined workings are connected by main drifts only to the central inclined workings, the upper and lower formation recesses drifts between the flank and intermediate inclined workings are extinguished, ventilation preparatory workings during the preparation period are carried out through the flank inclined workings, and treatment workings through the central s and the intermediate slant output, wherein the period between flank pillar mining and production of intermediate treatment workings airs through the inclined flank generation. 2. The method according to π. 1, characterized in that the ventilation wells are carried out at the lower boundary of the block, they are interconnected by a main transport drift, on which explosive-proof insulating jumpers are constructed at intermediate inclined workings from the side of the flank inclined workings, and ventilation is carried out along the inclined workings to the lower boundary of the block. ί