SU1599540A1 - Method of working gassy fire-hazardous seams in long pillars with roof caving - Google Patents

Abstract

The invention relates to mining and can be used to prevent endogenous fires and control gas evolution in the excavation field. The goal is to increase the fire safety of the method by eliminating the air exchange of the goaf with the existing workings through security preventive pillars and insulating structures. The preparation of the inclined field is started by the paired conduct of the inclines and the ventilation well from the day surface where the gas suction fan is installed. At the same time are preparing two adjacent excavation pillars. In the first pole, a ventilation drift is conducted, in the second, a paired conveyor drift. These drifts are connected by diagonal ventilation split furnaces. After the paired conveyor roadway, common to two pillars, is carried out, the mounting chamber for the mechanized complex passes. In parallel with the installation of the complex, a circular excavation is carried out to turn the complex and connect the first ventilation post drift and the second conveyor dual conveyor drift. The discharge of the outgoing jet is carried out in the direction of movement of the mechanized cleaning complex at any position in the panel. Ventilation streams are switched on twin workings using diagonal ventilated split furnaces. 1 hp f-ly, 1 ill.

Description

The invention relates to the mining industry and can be used to prevent endogenous fires and control gas release in the excavation field.

The purpose of the invention is to ensure the fire safety of the method by eliminating the air exchange of the goaf with the existing workings through

security preventive pillars and insulating structures.

The drawing shows the order of the workings and the direction of the air jets during the preparation and working out of the extraction poles.

The method is carried out as follows.

Preparation of the inclined floor is started by paired conducting of inclines 1 and 2 and

i borehole 3, on which the gas is installed: a suction fan. Compressed air is supplied to the limits of pillars I and II along two slopes, and the outgoing jet through well 3 is delivered to the surface. This makes it possible to eliminate complex and unreliable ventilation isolating devices, which are necessary for the opposite direction of the ventilation jets along slopes.

Then proceed to the simultaneous

cooking two (I and P) excavation pillars.

In this case, in the first (odd) pole, the ventilation duct 4 is wired, in the second (even) pole, the conveyor drift 5 is conducted pairedly. Outlets 4 and 5 are connected by inclined split furnaces along the strike in approximately the middle part of the pole. The presence of furnaces 6 makes it possible to exclude the holding of a flank slope and to organize a multitouch preparation

; workings. The installation of the complex in the first excavation column begins after the paired construction of the conveyor drift 7, and

: also mounting chamber 8, which are knocked off with drift 4. In parallel with the installation work, preparation for excavation and coal cleaning excavation in the first excavation column, the inclined split furnace 9 of the third pole, its conveyor drift 10, circular production 11 and finish preparation The first and second excavation pillars are paired by carrying out conveyor drifts 12 and 13, respectively. Installation of the complex is carried out at the Bremsberg in the mounting chamber 8, and in this case, if there are paired workings 4, follows contouring of the first half of this column (6 to split the oven). The order of switching of the ventilation jets in order to provide the required gas control is shown in FIG. one.

During the development of the first post, fresh air is directed through the ventilation drift 4 and fed to the cleaning face 8, and the outgoing jet is directed to the conveyor drift 7, the split furnace 6 of the 11th pole and the conveyor drift 5 to slope 2 and further to the well 3, through which it is discharged to the surface with the help of a ventilator installed at the well.

Part of the fresh air from the ventilation flap 4 is fed into the upper part of the furnace 6 of the 1st pillar to the ventilators installed here for airing during the dead ends of the workings 12 and 13. A fresh stream is also supplied through the drift 5, where the local ventilators are installed.

When working out the second and third pillars, after appropriate switching, a fresh stream of air is fed through the tongue 5 to one lava, and through the connections and the generation 5 to the other lava. Outgoing jet is directed according to workings 10

and 12, then through split furnaces 9 and B of even IV and II columns, through the drift 14 to the well 3 and to the surface.

When working out the first and second pillars, gas control in redeemed or stored openings 7 and 5, due to suction, part of the methane-air environment by the fan installed in well 3. The suction flow is adjusted to fireproof values in the exhaust space installed in bridges 14 , 15.

Example. An opening and preparation of a slope floor (slope 1 and 2, fig. 1) were completed to work out the “Nadbaikaiim” and “Baikaiim” layers with air supply from the active horizon. The outgoing jet was directed along one of the slopes to the hole, traversed to the level of the active horizon. Under this aeration scheme, substages were worked out in descending order. To release air from the sloping floor, a new well 3 was drilled with a diameter of 2.8 m to the lower slope of the inclined floor. At the same time, airing was provided in the cleaning stations x 8, which ensured the direction of the outgoing air stream towards the unworked part of the mine (inclined) floor. This scheme eliminated possible air swamps in the developed space, pressing them to the unworked coal massif.

When the turnaround of complex KK-2743 with the support of “Piome” in the lavas 11-112, 11-113 and 11-114 of the Baikai reservoir was accomplished, which corresponded to the I, II and III columns in FIG. 1, it was ensured that spontaneous ignition of the angle in the developed space was avoided and reliable gas control in the extraction field. For this purpose, the winding was carried out, the ventilation schemes for the left (5 positions) and the right (4 positions) turns were provided.

Claims (2)

1. A method of developing gas-bearing fire-hazardous formations with long pillars with roof collapse, including preparing lavas in the panel with drifts, sinking horizontal delineating workings with a smaller one-sided excavation site for the length of the lava, conducting circular openings, installation and ventilation split furnaces, testing lava columns, reversal of the mechanized cleaning complex and the implementation of an isolated removal of the outgoing air stream from the zone of active airing of the collapsed and deformed rocks along group ventilation development on the day surface, characterized in that, in order to increase the fire safety of the method by eliminating air exchange depleted space with existing workings through protective proflakticheskie tselnki and insulating structures, the slides pass paired, and in the middle part of the excavation pillars additional ventilation furnaces are carried out simultaneously with the installation of the complex in the mounting split kiln and they connect shchreki after conducting paired drifts to a ventilated split furnace, the outgoing jet being diverted along the gauge in the direction of movement of the mechanized cleaning complex by switching truy coupled to drifts, it is directed to Group vent generation portion and discharged through the vent hole, previously drilled in the group generation at the boundary bremsbergovoy bias or panel. 2. A method according to claim 1, characterized in that, in the descending order of mining of pillars, the ventilation well is drilled at the lower border of the panel.