RU2057934C1 - Process of exploitation of thick gas-bearing gently dipping seams - Google Patents

Abstract

FIELD: mining industry. SUBSTANCE: workings of lower layer are displaced towards completed column and rubble strip is left under intercolumn pillar of same width after advance of breakage face along lower layer. EFFECT: enhanced safety of process. 3 dwg

Description

 The invention relates to mining and can be used in the layered development of powerful gentle, mainly potassium gas-bearing formations.

 There is a method of developing shallow gas-bearing powerful potash strata in two layers in a descending order [1], which includes drawing contouring pillars of layer workings and simultaneously working out layers with an underwork of workings of the lower layer and with cutting in to the worked out space of the excavation drift in the upper layer.

 This method does not find wide application because of the high cost of maintaining the near-bottom production, through which fresh air is supplied and the inability to isolate it from the flow of combustible gases into the working zone of the lava from the worked out space of an adjacent column. In the pressure zone, a pillar with a width of 2.5-3.5 m, separating the near-surface mine from the worked-out space of the neighboring trunk, is destroyed, and combustible gases are sucked in through cracks due to the ejector effect from the worked-out space to the transport drift of the upper lava and are delivered to it slaughter.

 There is also known a method of developing gas-rich powerful flat beds, prone to spontaneous combustion, with two inclined layers in descending order by long columns with working faces for falling, leaving pillar pillars and carrying out preparatory workings in each layer [2] At the same time, to prepare each excavation column in the bottom layer spend one working, connecting it to the workings of the upper layer by failures, and when working out the layers of the excavation column in front of the face of the upper layer in cross-cutting to the adjacent cut tannomu extraction pillar in the lower layer is carried out a second generation, combining it with sboyka, previously traversed by the preparation of an adjacent exhaust extraction pillar.

 However, when mining salt formations, with almost horizontal bedding, combustible gases from an adjacent spent column will enter the faces of an adjacent column.

 Closest to the proposed one is a method for the development of shallow gas-bearing powerful potash formations of complex structure in two layers in a descending order [3] taken as a prototype and including drawing contouring pillars of the mine workings and simultaneous descending mining of the layers, leaving inter-pillar barrier pillars 80 m wide. reliable isolation of adjacent posts. However, due to large losses of minerals and a large amount of preparatory workings, the scale of application of this method is small.

 The purpose of the invention is the reduction of mineral losses and the cost of maintaining the mine workings in the lower layer, increasing the safety of mining by eliminating the penetration of adjacent adjacent extraction column into the working area of paired lavas of combustible gases, reducing the volume of preparatory workings.

 The goal is achieved by the fact that in the pillar pillar of reduced width, transport drifts of the upper and lower layers are carried out, placing the latter in the zone unloaded by the developed space of the upper lava, and the negative effect of the upper part of the pillar of the pillar on the bottomhole space of the lower lava and preparatory workings on the lower layer in the knowledge of the effect of the pillar it is eliminated by laying out a rubble strip under it after moving the bottom face, with a width of at least one width of the overlying pillar.

 In FIG. 1 is a flow diagram of a two-layer reservoir excavation, plan view; figure 2 is a section along the face of the upper lava (aa in figure 1); figure 3 is a section along the bottom of the lower lava (BB in figure 1), where 1 conveyor and 2 transport are common for both layers drifts conducted in the lower layer; 4 faults for cutting the central ventilation 3 and 6 and transport 7 and 8 drifts of the lower and upper lavas, 5 conveyor drift of the upper lava, 9 formation faults on the upper layer, 10 ore passages, 11 rubble strip, 12 conveyor drift of the adjacent extraction column.

 The method is as follows.

 To prepare the extraction pillars in each layer for mining with double-mine lavas, first conveyor 1 and transport 2 drifts in the lower layer and failures 4 for cutting central ventilation 3 and 6 and transport 7, 8 drifts of the lower and upper lavas are common for both layers. The conveyor drift 5 of the upper lava is carried out with an offset towards the massif and is shot down by formation faults 9 along the upper layer with ore passes 10 with a common conveyor drift of the upper and lower lavas 1.

 Thus, between the workings 1 and 5, leave the tape pillar "a" along the lower layer, in this pillar on the adjacent panel, in the unloaded zone (after working out the upper lava), transport drift 8 of the lower lava of the cut column using technological failures 4.

 At the same time, from the side of the adjacent column, the continuous pillar remains on the lower layer and the pillar on the upper layer (C), isolating the fresh stream of the worked column from the worked out space of adjacent columns. To eliminate the stamping effect of the pillar (C) on the lower lava lining, coaxially with it in the worked out space of the lower lava, after moving the face, under the protection of the lining [4] lay a rubble strip or bonfires for the second support formed from the pillar of the rock console in the roof of the lower lava . This increases the safety of mining, reduces the loss of minerals, improves the conditions for maintaining mine workings, virtually eliminates the possibility of leakage of combustible gases from the worked out space of an adjacent column.

Claims (1)

 METHOD FOR THE DEVELOPMENT OF POWERFUL GAS-BEARING GANFLEEP FLOORS, including conducting in the pillar of the pillar the preparatory workings of the lower layer in the discharge zone under the worked-out space of the upper layer with an offset relative to the cross section of its layered workings and under the protection of the interlayer stack of rocks, characterized in that the workings of the lower layer are shifted to the side of the spent column and after moving the working face along the lower layer, a rubble strip of at least its width is left under the entire pillar.

Images