RU2011823C1 - Method for mining of thick steep fire-hazardous coal seams - Google Patents

Abstract

FIELD: mining industry. SUBSTANCE: method consists in driving development workings, extraction of upper part of level by downcast layers with provision of hardening fill in worked out space, and mining of lower part of level with roof rock caving under protection of flexible roofing mounted in inclined mounting layer. Formation of stable artificial level pillar is performed by working upper part of level, first, with horizontal layers, and then, with transverse inclined layers of variable thickness with imparting angle of natural slope to caved roof rocks. Working of inclined mounting layer is carried out with breakage of roof rocks over entire height of level by blasting charges in long holes. EFFECT: higher efficiency. 2 cl, 8 dwg

Description

 The invention relates to the mining industry and can be used in the development of powerful steep fire hazardous coal seams.

 The aim of the invention is to prevent the bypass of foci of endogenous fires of an overlying floor by forming a stable artificial interfloor pillar.

 In FIG. 1 shows a diagram of mining the upper part of the floor in descending horizontal layers with a bookmark; in FIG. 2 is a section AA in FIG. 1; in FIG. 3 - scheme of working out the lower part of the floor with the collapse of the roof; in FIG. 4 is a section BB in FIG. 3; in FIG. 5 is a section BB of FIG. 1; in FIG. 6 is a section GG in FIG. 1; in FIG. 7 is a section DD in FIG. 3; in FIG. 8 is a section EE in FIG. 3.

 The excavation unit of a powerful steep fire hazardous coal seam is opened by intermediate crosshairs 1 on the return horizon from the field recoil drift 2 and on the ventilation horizon from the field ventilation drift 3. Between the intermediate crosshairs at the near and far boundaries of the extraction block near the soil and the roof of the formation, coal slopes 4 are drawn along the coal and 5. The mining of the upper part of the floor is done in descending horizontal layers with a hardening tab of the worked out space. For example, three horizontal layers 6 are initially worked out. For example, each horizontal layer is processed in the direction from the far boundary to the near boundary of the extraction block. Coal mining in the layers is performed, for example, by diagonal feedthroughs using a GPKS tunneling machine.

 In each entry, coal is excavated, the conveyor is moved, flexible flooring is laid, the support is erected with embroidery, the roof conveyor layer drift is erected. After that, from the advanced ventilation layer drift, placed in the backfill array of the overlying layer, a hardening bookmark is fed into the removed entry.

 The diagonal entries of the underlying horizontal layer are placed perpendicular to the diagonal entries of the overlying layer, so the metal flexible overlapping tapes laid in the previous layer along the bottom are converted into flexible metal upper layers laid across the lower layer entry. Ropes are passed along the drifts at the roof and soil of the formation to which the ends of the flexible overlapping tapes are attached, and the ropes themselves anchor to the lateral rocks.

After working three horizontal layers begin testing of, for example, two transversely-inclined layers 7 and 8. In developing layer 7 its soil at an angle of ^20-25 ° to the horizontal, with the height of the face near the soil formation 5.0-5.5 m. Following the treatment face of the transverse-inclined layer 7, the layer drifts 9 and 10 pass with some lag, the layer drift 9 passing directly under the flexible overlap at the top of the formation, and the layer drift 10 pass near the soil of the formation so that the soil of the transverse-inclined layer is located at an angle ^of 45-60 to the Horizon y, equal to the angle of repose φ caving.

 After mining layer 7 and the failure of the layer drifts 9 and 10 with carbon slopes 4 and 5, the mining of the transverse-inclined layer 8 begins.

 Simultaneously with the development of layers 6 and the transverse-inclined layer 7, layered drifts 11, 12 and 13 are carried out at the top of the formation to prepare, for example, three lavas 14.15 and 16 of the installation inclined layer and sub-floor drifts 17 at the formation soil for working out the lower layer 18. The development of the transverse-inclined layer 8 is carried out simultaneously with the mining of the upper mounting lava 14. When mining the layer 8 on its soil, a flexible flooring 19 is made of metal tapes and a metal mesh laid on top of the metal tapes, and it is attached to the soil pl Over one hundred anchors 20 mesh lay film or burlap to prevent seizure of the flexible covering material with stowing the hardening reaction. The filing of the bookmark into the worked out space is carried out alternately from two drifts with simultaneous redemption. After working off the last transverse-inclined layer 8 on the ventilation horizon in the upper part of the floor, an artificial mezzanine pillar 21 is formed from stable filling material.

 An artificial horizontal horizon, including five to six layers of flexible overlap, the space between which is filled with a hardening tab, has an increased bearing capacity. This design of the artificial pillar significantly increases its stability during the underworking. The face of the upper mounting lava 14 is associated with the face of the transverse-inclined layer 8. The flexible floor 22 laid on the soil of the mounting lava, in its upper part, is fixed to a rope to which the flexible floor 19 attached on the soil of the transverse-inclined layer 8 is attached. The lower edge of the flexible floor 22 is led into a layered conveyor drift 11, where it is attached to the rope. Roof landing in assembly lava 14 is carried out by blasting charges in wells 23 drilled into the formation roof to a depth of 5-10 m. Before planting roofs along the face and above conveyor drift 11, fires 24 are laid out. Following the upper assembly lava 14 with a lag of 15- 20 m put into operation the second lava 15, and then with the same lag and the lower mounting lava 16.

 The preparation of the lower layer 18 for the cleaning recess consists in driving sub-floor drifts 17, coal-blasting furnaces 25 and inclined roofs 26. The processing of the lower layer 18 is carried out under the protection of an artificial interstitial pillar 21 using conventional technology with blasting of coal using drilling and blasting operations from sub-floor drifts 17, coal-blasting furnaces 25 and inclined unit roofs 26. Roof rocks previously loosened to a considerable depth during mining of the inclined installation layer by blasting charges in long wells move at an angle φ after behind the coal excavation in the lower layer, they fill the mined-out space and add up an interfloor artificial pillar, preventing endogenous fires from passing from an overlying floor.

Claims (2)

 1. METHOD FOR DEVELOPING POWERFUL STEEP STEAM FIRE HAZARDOUS COAL LAYERS, including preparatory workings, mining of the upper part of the floor in descending layers with a hardened laying of the worked out space, and the rest of the floor with collapse of the roof under the protection of a flexible ceiling mounted in an inclined installation layer, which is different , in order to prevent the bypass of foci of endogenous fires of an overlying floor by forming a stable artificial interfloor pillar, working out the upper part of the floor e original horizontal layers are then transversely inclined layers of variable thickness to impart soil last layer transversely inclined angle of repose of the collapsed roof rock.  2. The method according to p. 1, characterized in that, in order to increase the stability of the artificial interstore pillar by continuously bribing the destroyed rocks of the roof, the development of the inclined mounting layer is carried out with the destruction of the roof rocks over the entire height of the floor by blasting charges in long wells.

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