RU2143074C1 - Method of mining of thick inclined outburst-phone seam - Google Patents

Abstract

FIELD: mining; applicable is safety mining of thick inclined outburst-prone seams of coal by shearers. SUBSTANCE: panels are worked by slices downward and slices are extracted by pillars along the strike upward and through every other one over entire area of panel. In this case, pillars adjacent to worked out ones are temporarily retained, and depth is determined of zone pressed out by rock pressure or artificially loosened by blast in which new belt headings run with concurrent extraction of coal. Then, coal is won from temporarily retained pillars above new belt headings, and fracturing in roof in front of breakage faces is observed from these headings for subsequent roof caving with rock sliding over fracture sides. Underlying slices are worked under caved rocks of upper slice roof and coal intercalations of overlying slices. EFFECT: higher efficiency and safety of mining of thick inclined outburst-prone seams in panel. 2 cl, 2 dwg

Description

 The invention relates to the field of mining and can be used for the development of powerful coal seams during the harvesting excavation with safe mining.

 There is a method of developing close coal seams by adjusting the size of the floors in conjunction with crack formation of the roof (AS USSR N 1514933, CL E 21 C 41/04, 1989). Using this method, the moment of formation of technogenic cracks in the hard-to-collapse roof is determined, according to which the dimensions of the worked floors of the first layer are established and the floors are worked through one, the subsequent layers are worked out with the first layer and the floors are worked out in them in a checkerboard pattern with the floors of the previous layers and the development of technogenic cracks in the roof. The method improves the management of the roof during mining floors in the formation. The disadvantage of this method is to link the dimensions of the floors to the beginning of cracking of the roof, which, with strong rocks and a delay in the collapse of the roof, creates an increase in the size of the floors and additional loadings on the formation associated with dangerous manifestations of rock pressure. Therefore, the use of the method for the development of shock hazardous formations is inefficient.

 There is a method of developing a mineral by changing the sequence of its extraction by cameras in various areas and reducing rock pressure by laying out the worked out space (USSR AS N 989070, class E 21 C 41/06, 1983). According to this method, minerals are extracted by chambers at a reference pressure lower than the strength of the interchamber pillars, and when they are commensurable, they carry out cleaning work in another section, and waste chambers are laid in the previous sections, after which other chambers are worked out, simultaneously behind the reference pressure zone from the cleaning operations of such chambers work out the pillars of minerals located between the laying of the worked out space. The method provides alternate mining of minerals in various areas with control of rock pressure. The disadvantage of this method is the difficulty in determining the commensurability of the reference pressure with the strength of the sections to stop excavation in the section and transfer to another section, which saves the risk of harmful manifestations of rock pressure. In addition, the transition of sewage treatment from one site to another and the implementation of laying work violate the rhythm of the excavation. Therefore, the use of the method for mining a shock hazardous formation is inefficient.

 A known method for the development of shallow formations by separating the excavation fields and alternately excavating the pillars in them (AS USSR N 800370, class E 21 C 41/04, 1981). According to this method, together with drifts at the horizon, an intermediate drift passes, dividing the horizons into upper and lower excavation fields, and before the column is mined, the preparation of the adjacent one is completed in the lower excavation field, while prepared columns in the upper excavation field work out the prepared columns in the upper excavation field excavation field. The method increases the intensity of development due to the simultaneous extraction of columns in the upper and lower fields. The disadvantage of this method is the separation of technological processes in excavation fields, which is associated with the difficulty of controlling the roof and the possibility of creating increased reference pressure in individual columns, therefore, the use of the method for working out shock-hazardous formations is inefficient.

 A known method of developing a bed with pillars with their alternate extraction ("Technological schemes for the development of seams in coal mines", part I, IGD named after A. A. Skochinsky, M., 1991, S. 42-44). According to this method, the formation is worked out by panels with alternating recesses through the pillar and collapse of the roof after the movement of the faces. The method provides continuous testing of panels due to the systematic excavation of columns. The disadvantage of this method is the inconsistency of the excavation of the pillars and the subsequent collapse of the roof with the development of rock pressure, which creates a danger of harmful forms of its manifestation, therefore, the use of the method for developing a shock-hazardous formation is inefficient.

 Closest to the invention in technical essence is a method of developing powerful coal seams with layer-by-layer excavation strips (AS USSR, N 825961, class E 41/04, 1981). According to this method, a powerful layer, prone to mountain impacts and sudden outbursts, is worked out by inclined layers in a descending order, and in layers by strips with the moving faces in mutually perpendicular directions, and the upper layer is worked out by falling strips using the worked out space of each previous working strip the subsequent strip with simultaneous mining in the upper layer of at least two bands, and the mining of the upper and lower layers is carried out in adjacent excavation fields. The development of the strips of the upper layer is connected by duchki with the reservoir workings of the lower layer, which is carried out under the worked-out space of the upper layer, and the preparation of its development is carried out by sinking through the rock of the recoil and ventilation field drifts.

 The method provides continuous mining of excavation fields with a systematic cleaning recess of the layers in mutually perpendicular directions. The disadvantage of this method is the possibility of the manifestation of rock shocks in the supported parts of the worked out space when used in adjacent bands, as well as the difficulty of controlling rock pressure when moving the front of the treatment works in the layers in mutually perpendicular directions. In addition, the method provides for field training with the passage through the rock of haul-off and ventilation drifts and connecting ducts along the reservoir between the layers, which is associated with an increase in the costs of driving the workings and their maintenance. Therefore, the use of the method for developing powerful shock hazardous inclined formations is inefficient.

 The inventive method solves the problem of increasing the efficiency and safety of the development of powerful shock hazardous inclined formations.

 To do this, the columns in each layer are worked out along the strike of the formation in an ascending order and through one on the entire panel area, and the columns adjacent to the spent ones are temporarily left, the zone pressed by the forces of rock pressure is measured in the left columns in the upper layer of the panel, its depth is determined and passed new conveyor drifts in it, and coal from their penetration is simultaneously removed, then coal is removed in temporarily abandoned columns above new conveyor drifts, new ones eat and grow in the roof of the formation ahead of the faces natural cracks, and the roof is planted following the movement of faces, taking into account the slip of the rocks along the sides of these cracks, and the underlying layers are worked out under the collapsed rocks and coal layers of the overlying layers. In addition, when the depth of the pressure from the mountain pressure is not enough for the new conveyor drifts to be carried out, the zones from the ventilation drifts are drilled into the reservoir, charged with explosive charges, explode charges and new conveyor drifts pass in the zone that has been loosened by charges.

 The method is illustrated by drawings, where in FIG. 1 is a diagram of mining a panel of a powerful shock hazardous inclined formation with moving the front of the treatment works to revolt at the time of excavation of the temporarily abandoned posts; in FIG. 2 - section I - I with the development of layers and cracking in the roof of the reservoir.

 The method is as follows. In the developed powerful impact-hazardous inclined formation 1, a flank slope 3 passes along the entire length of panel 2 to fall. Mounting chambers 5 pass from the slope 3 along the lower border of the panel 2 along the upper layer 4 of the formation 1, from which pillars 6 begin to be cut along the upper layer 4. Columns 6 take out along strike in ascending order and through one. They are practiced over the entire area of panel 2. Following the movement of the faces 7 in the pillars 6, the roof rocks 8 are collapsed. The posts 9 adjacent to the spent posts 6 are temporarily left. In the upper layer 4 of panel 2, in zone 10 temporarily left by the columns 9, the area 10 pressed out by the pressure of the mountains is measured, its depth is measured and the new conveyor drifts 12 and the old conveyor drifts 13 from the spent pillars pass uprising from the 6 ventilation drifts 11 along the columns. 6 are used as ventilation. If the zone 10 from the ventilation drifts 11 is not enough for the new conveyor drifts to be carried out by the mining pressure 11 from the drift holes 6, they are drilled into the formation 1 in front of the faces 14 of the well 15, charged with explosive charges 16, charges 16 explode, and new conveyor drifts 12 pass in zone 16 forcibly loosened by charges 16. Coal from driving new conveyor drifts 12 is simultaneously removed and transported to the opposite flank of panel 2. Pass in the posts 9 above the new conveyor drifts 12 measures 17 and in the same order as the pillars 6, work them out together with the pressed rock pressure forces or forcefully loosened zone 10 along the upper layer 4 to the length of the entire panel 2. Ahead of the movement of the faces 14 in the posts 9 in the new conveyor drifts 12 observe the appearance and the emergence of new natural cracks in the roof 18. Following the movement of faces 14 in columns 9, as in columns 6, the roof is planted, while the rocks 8 of the roof are collapsed using sliding along the sides of the cracks 18. After working off all pillars 6 and 9, top layer 4 layer 1 the underlying layers work out 19. They are worked out under the collapsed rocks of the roof 8 of the upper layer 4 and coal layers 20 from the overlying layers.

 The development of a powerful shock-hazardous inclined formation by the claimed method is based on the efficient and safe treatment operations with the extraction of columns in the panel in two stages and the use of rock pressure to weaken the marginal zone of the columns, cracking of the roof and reducing the formation loads in the face. When the posts are temporarily left adjacent to the spent ones, the edge zone under the influence of rock pressure forces undergoes extraction and protects conveyor drifts from dangerous manifestations of rock pressure. The same function is performed by the formation zone, forcibly loosened by explosions, above the ventilation drifts with insufficient extraction of coal by rock pressure. The loosened coal of these zones when driving new conveyor drifts is removed with a reduction in energy costs compared to the costs of maintaining ventilation drifts when using them as new conveyor drifts. At the same time, there is a passing coal mining from tunneling. New conveyor drifts are protected by loose coal from the manifestations of rock pressure in the working faces during the mining of temporarily abandoned pillars. The appearance and germination of cracks in the rocks of the roof occurs under the action of rock pressure forces, which increase when the front of the treatment works moves to the worked out space and a decrease in the number of temporarily left pillars. These cracks improve the breakability of the rocks during the planting of the roof and can reduce its step due to the sliding of the rocks along their sides, and the reduced step of the planting of the roof, in turn, reduces the load of the formation in the working face. Testing the panel from the bottom up in an ascending order reduces the depth of the treatment work and, accordingly, the stress in the working faces, and the movement of faces in the posts along the strike in all layers improves the management of rock pressure by roof collapse. These positive signs prevent the concentration of formation loads in the working faces during mining of the upper layer and exclude the occurrence of rock shocks. The mining of the underlying layers of the formation after mining of the upper layer under the collapsed rocks of the roof prevents the dynamic manifestation of rock pressure in the shock-hazardous formation due to the protective discharge from the excavation of the upper layer, and the abandonment of coal layers eliminates the dilution of coal by the collapsed rocks.

 This embodiment of the method improves the efficiency and safety of developing a powerful shock-hazardous inclined formation due to the sequential layer excavation of the panel and the development of pillars in an ascending order through one using rock pressure forces. In comparison with the prototype, the excavation of the pillars and the movement of the front of the cleaning excavation in the panel are coordinated with the development, management and use of rock pressure, which, when mining the upper layer, creates a protective barrier zone to protect the transport workings, and additional cracks are induced in the roof, allowing to reduce the pitch of its landing with the effect of reducing the impact of shock hazardous formation in the face. Field rifled preparation is absent, and transport workings are carried out with a reduction in energy costs with associated production from tunneling.

Claims (2)

 1. A method of developing a powerful inclined shock-hazardous formation, including driving the workings in the panel, working it in layers in a descending order with excavation of the formation in columns and collapse of the roof following the movement of faces, characterized in that all the columns in each layer work out along the strike of the formation in the ascending in order and through one over the entire area of the panel, and the columns adjacent to the spent ones are temporarily left, the zone pressed by the forces of rock pressure is determined in the left columns in the upper layer of the panel, its depth is measured and passed into new conveyor drifts to it, and coal is removed from their penetration along the way, then coal is removed in temporarily left pillars above new conveyor drifts, they are observed from the front of the faces of the emergence and germination of new natural cracks in the formation roof and the roof is planted following the movement of faces, taking into account the slip rocks on the sides of these cracks, and the underlying layers work out under the collapsed rocks and layers of coal overlying layers.  2. The method according to claim 1, characterized in that, when the depths of the pressed mountain forces are not enough for the new conveyor drifts to be carried out, the zones from the ventilation drifts are drilled into the wellbore, charged with explosive charges, the charges are blown up and new conveyor drifts pass in the zone that has been loosened by charges .

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