RU2472931C1 - Control method of poorly caving roof at mining of gas-bearing formations in faces with mechanised complexes - Google Patents

Abstract

FIELD: mining.

SUBSTANCE: as face advances from special chambers passed above preparatory minings on the side of extraction galleries there drilled opposite each other are wells parallel to formation at the distance from lower plane of the main roof to wells, which is determined by the following formula: L_llr=l₃(1+√K_l) / (K_l -1), where K_l - rock loosening coefficient of the main roof at their blasting with loosening; l₃ - distance from the main roof to fallen rocks, m; l_llr - line of least resistance of blasting cone, m. Then, they are charged and blasted after the support line in the worked-out space. At each explosion there created is support from roof rocks fallen out of funnels throughout the face length, by means of which free falling of main roof, which is torn by explosion, is prevented.

EFFECT: considerable increase in mining of gas-bearing formations by means of mechanised complexes in wide range of coal bed in bedding zone of coal formations.

4 dwg

Description

The invention relates to the mining industry and can be used in lavas with mechanized complexes when mining gas-bearing formations with hard-to-collapse roofs in a wide range of conditions of occurrence of coal seams.

The well-known "Method of managing hard-to-collapse roofs", including the creation of rubble strips in the worked-out space, one of which, the central one, is laid out parallel to the face line 0.2 _L in length and 0.2 in the established step of the collapse of the main roof (patent SU No. 2177546, publ. 12/27/2001).

The disadvantage of this method is the high risk of work on the construction of rubble strips in the worked out space, in which it is difficult to ensure normal ventilation of the area where the work is being done, and there is a danger of unplanned collapse of the roof at the place of construction of the central rubble strip.

The well-known "Method of managing hard-to-collapse roofs in working faces", characterized in that the destruction of the main roof into blocks equal to the natural step of collapse, is carried out before the start of treatment works, leaving a pack of rock adjacent to the coal seam. The boreholes are positioned in such a way that when the explosive is blasted, the roof layers over the coal seam remain intact, which protect the bottom hole from spilling of the destroyed rocks during the movement of the main roof block (a.c. SU No. 3111011, published 09.08.1971).

The disadvantage of this method is that when large blocks of the main roof collapse, they squeeze out the methane accumulated in the working space into the working space of the treatment and preparatory workings of the excavation area, and as a result a dangerous situation is created for people in the workings.

The well-known "Method of managing hard-to-collapse roofs in the development of coal seams by mechanized complexes", in which at a given working distance of the pillar, an artificial roof is artificially planted by reorienting the placement of the formed rock blocks parallel to the edge of the face with the displacement of the collapse of the roof in the direction of the blockage outside the lava working space. To implement the method, wells are drilled into the side of the conveyor drift at a distance of 0.8-1.0 m from each other, in which explosive charges are mixed and exploded. In this case, the collapse line of the main roof shifts towards the blockage, as a result of which the mechanized lining is protected by the main roof console and does not experience destructive loads during the next collapse of the main roof. In this case, the complexity of drilling holes is reduced, since this work is carried out not by rock, but by coal (patent RU No. 2151293, publ. 06/20/2000).

The disadvantage of this method is that the collapse of the roof occurs in large blocks, which, when falling onto the soil of the formation, squeeze methane accumulated in the blockage from the developed space into the bottom hole and into the preparatory workings, as a result of which a dangerous set-up is created for people working on the site. This factor is the main disadvantage of this method.

Closest to the technical nature of the claimed method is the "Method of controlling a hard-collapsing roof in the working faces", adopted as a prototype (ed. St. SU No. 313979, publ. 07.09.1971). When implementing the method, prior to the start of treatment work, drills are drilled from the drifts by a vertical fan and blast in the worked out space after moving the working face beyond the line of wells by the value of the radius of the explosive funnel. The collapse in the explosion of a plate of rocks of the main roof occurs behind the lining line and therefore excludes its impact on the mechanized lining during the first precipitation.

The disadvantage is that the method does not exclude the extrusion of gas from the developed space into the bottomhole zone of the lava during the collapse of the slab of the main roof. For this reason, the method does not ensure the safe conduct of treatment in lavas during the development of gas-bearing formations.

The technical result is to increase the safety of working gas-bearing formations in a wide range of conditions.

The technical result is achieved by the fact that in the method of controlling a hard-to-collapse roof during the development of gas-bearing formations in lavas with mechanized complexes, including drilling wells from the side of preparatory workings in the roof rocks, loading and blasting them behind the roof support in the worked-out space, creating supports from the rocks that have precipitated from explosive funnels , preventing the free collapse of the main roofing plate torn off from the array, the wells are drilled parallel to the bedding, and the distance from the lower plane main roof to the wells determined by the formula:

where K _p - coefficient of loosening of the rocks of the main roof when blown by their loosening;

l _s - distance from the main roof to the collapsed rocks immediate, m;

l _lns - line of least resistance of the explosion funnel, m.

Drilling wells parallel to the bedding at a distance determined by the ratio of the values of l _s , l _lns and K _p allows us to create a more reliable support for the main roof torn off the slab massif along the entire length of the lava and thus prevent its free lowering at different values of the removed formation thickness and the ratio named quantities.

The invention is illustrated by drawings, which show the following details of the method: figure 1 is a vertical section of the rocks of the roof along the fall line of the reservoir of the excavation section in the normal to the reservoir plane of the location of the wells of the next explosion; figure 2 is a vertical section of the rocks of the roof in the normal to the reservoir plane of the location of the wells after the explosion; figure 3 - the location of the artificial supports from the rocks that spilled out during the explosions as the lava moves; figure 4 is a vertical section of the rocks along the line of fall of the reservoir in the area of the blown funnel.

The method is as follows. The preparation of the excavation site for mining the coal seam 1 (Fig. 1), above which shale lies (direct roofing) 2, above which sandstone 3 is located, is carried out by paired drifts 4, 5, 6, 7. Chambers 8 pass over the drifts over certain distances and 9. From the chambers, wells 10 are drilled parallel to the bedding at a distance of 15 from the formation, which is determined by the above formula. The charges in the wells are located along their entire length. An exception is the sections of wells 11 filled with stemming. After blasting the wells, loosened rocks 16 (Fig. 2) fill the volume of the funnel and the gap 14 located under it between the main roof and the soil of the formation or the rocks of the immediate roof collapsed when the lava is moving 12. The charges are blown up in the wells periodically in the worked out lava space behind the mechanized roof support 17 (figure 3) and by loosening the rocks of the main roof create supports 16, on which base plates of the main roof torn off from the array are supported and with the help of which they prevent the free collapse of the torn off from the mass and through line 18 (Figure 3) of the main roof tiles. As a result of this, the gas (13) located in the worked out space before the explosion is not squeezed out into the bottomhole space of the lava and into the preparatory workings in which people are located.

Blasting of elongated charges in wells is carried out by loosening. The radius of the funnel 19 during the explosion of rocks by loosening is equal to half the value of the line of least resistance 15, i.e. r = 0.5l _ls (Fig. 4).

Complete re-framing of the rocks of the main roof in the funnel zone is ensured by observing equality:

where the left part represents the increase in the volume of rocks of the main roof due to their loosening in the volume of the funnel, and the right part represents the volume of loose rocks in the ACEF gap.

From the similarity of triangles, DBC and KSE find expressions for determining the quantities

KE = FL = 0.5l _s ,

The found expressions for r and КЕ are substituted into formula (2) and a quadratic equation is found to determine the line of least resistance when blasting the rock by loosening (distance from the wells to the lower plane of the rocks of the main roof):

Solve equation (3) and find the desired expression (1).

Example: m _in = 3.5 m - the removed capacity of the reservoir;

m _nk = 2.0 m - the power of the immediate roof;

K _p = 1.5.

In this case, l _z = m _in + m _n.k. -K _p · m _n.k = 3.5 + 2.0-1.5 · 2.0 = 2.5 m.

Substituting these data in the formula (1), we obtain:

It follows that the wells should be drilled at a distance of 11.1 m from the reservoir.

The application of the method can significantly improve the safety of treatment operations during the development of gas-bearing formations using mechanized complexes in a wide range of conditions.

Claims (1)

A method for controlling a hard-collapsing roof during the development of gas-bearing formations in lavas with mechanized complexes, including drilling wells from the side of preparatory workings in the roof rocks, loading and blasting them behind the support in the worked-out space, creating supports from the rocks that precipitated from the blasting funnels, preventing free collapse of the rock torn from the massif slabs of the main roof, characterized in that the wells are drilled parallel to the bedding, and the distance from the lower plane of the main roof to the well Jin is determined by the formula

where K _p - coefficient of loosening of the rocks of the main roof when blown by their loosening;
l _s - distance from the main roof to the collapsed rocks immediate, m;
l _lns - line of least resistance of the explosion funnel, m.

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