RU2147682C1 - Method of mining of thick gently dipping seam by short faces in diagonal layers - Google Patents

Abstract

FIELD: mining industry, particularly, underground coal mining. SUBSTANCE: method includes, after driving of development workings, separation of district by middle diagonal ventilation-stowing rise entry into upper and lower parts. Both parts are extracted by chambers in direct run and by stopes in reverse running in diagonal pillars located in upper part of district along middle diagonal ventilation-stowing rise entry, and in lower part, square to it. Width of stope is taken equal to 2.5 m, and 2/3 of coal volume, in half of layers near seam roof, is worked with self-flowing delivery of broken coal to conveyer section cross-cut, and 1/4 of coal volume, to conveyer cross adit. In half of layers, near coal seam floor, coal is additionally transported through boundary conveyer connections located on seam floor. In this case, tunneling machine is delivered to chamber from self-flowing delivery rise entries and conveyer through-cut at natural obtuse angles of diagonal pillars. Men and equipment are delivered to blocks to be extracted over boundary horizontal working, and effluent air streams in half layers near seam roof are additionally withdrawn over boundary ventilation-stowing connections. EFFECT: more economic and adaptable to production coal mining. 4 cl, 5 dwg

Description

 The invention relates to the mining industry, namely to underground coal mining.

 There is a method of developing a powerful flat bed in a descending order with the full laying of the worked-out space and using horizontal layers [1]. The disadvantage of this method is the large length of the horizontal workings in which coal is transported mechanically.

 The closest technical solution is the method of developing a powerful flat formation with inclined layers in a descending order with a full laying in long lavas of the worked out space [2, 3]. The disadvantages of the method are the high complexity of the treatment in long lavas and the high cost of mechanized complexes used in lavas.

 The essence of the invention lies in the fact that in the method of developing a powerful flat formation with short faces in the diagonal layers in each layer, after conducting field preparatory workings, the field is divided by the middle diagonal ventilation and filling furnace into the upper and lower parts, which are removed by cameras with a forward stroke and set points with a reverse stroke in diagonal columns located in the upper part of the field along the middle diagonal ventilation and filling furnace, and in the lower - perpendicular to it, while the width of the entry is taken augmented 2.5 m, and for 2/3 of the volume of coal in half of the layers near the top of the seam, the excavation is carried out with gravity delivery of beaten coal to the conveyor precinct cross-turn and 1/4 of the volume to the conveyor cut, and in half of the layers near the soil of the coal, transported along the boundary conveyor faults, which are located on the soil of the reservoir, while the driving of the roadheader into the chambers is carried out from gravity-feed delivery furnaces and the conveyor clearing at natural obtuse angles of the diagonal pillars. The delivery of people and equipment to the extraction fields is carried out according to the horizontal horizontal output, and outgoing air jets in half of the layers near the top of the formation are additionally taken out along the boundary ventilation and filling faults.

 Dividing the field of the middle diagonal ventilation and filling furnace into the upper and lower parts with different locations of the diagonal columns provides a half reduction in the cost of transporting coal compared to the analogue and prototype, despite the partial delivery of coal by gravity along the boundary conveyor faults of the lower layers of the formation. The costs of driving a tunneling machine into cameras are also reduced.

 The use of openings with a width of 2.5 m allows the use of short-digging treatment mechanisms and reduce depreciation by 3/4 compared to the long lavas that are available in the prototype.

 The use of diagonal layers makes it possible to have one horizontal boundary development for all layers to deliver people and equipment to the faces.

 As a result of the use of diagonal pillars in the diagonal layers, the development efficiency is significantly increased: labor costs are reduced by a third and the concentration of work is doubled in comparison with the analogue and prototype.

 The proposal is illustrated by drawings.

 In FIG. 1 shows the section of the formation by dip at the right boundary of the site, A-A; FIG. 2 is a top view of the diagonal section of the reservoir, a plan of the middle layer being developed, B-B; FIG. 3 is a top view of a diagonal section in the worked out part of the formation, C-C; FIG. 4 is a top view of a diagonal section in the unworked part of the formation, D-D; FIG. 5 is a plan view of a horizontal section of the formation at the level of the horizontal horizontal output, K-K.

 The method is as follows.

 The treatment section is prepared by field haulage 1 and field ventilation 2 drifts, as well as by district cross-valves 3-6 at its borders, respectively, on haulage and ventilation horizons. From district crosshairs to the formation, four 7-10 gesenkas were passed to the soil, and then to the roof of the formation. All of them are used for air supply, filling material and descent of coal. Gesenki on the retreat horizon as the layers are developed are extinguished (see Fig. 1). Between themselves gesenki knocked down by conveyor 11 - 12 and ventilation-filling 13 - 14 glades. Sludges 12 and 14 correspond to the worked-out layers and after they have been worked off, they are cleared, and for the underlying layer, new openings 15 - 16 go through. Before the coal is mined, the layers also have a horizontal horizontal output 17, which is necessary for people to approach and supply equipment to the working faces of the worked-out layers. With each layer, the horizontal output is knocked down by a race, for example, 18 (see Fig. 5).

 In each layer, the field is divided by the middle diagonal ventilation and filling furnace 19 into upper and lower parts, which are taken out by chambers 20 in the forward course and inlets 21 in the reverse course in diagonal columns 22. In half of the layers near the top of the seam, the recess leads to 2/3 of the volume of coal with gravity delivery of beaten-off coal to the conveyor precinct crosscutter and only 1/4 of the volume with gravity delivery to the conveyor clearance. After the chambers, coal descends through the delivery and gravity furnaces 23-24. In half the layers near the formation soil, coal is additionally transported along boundary faults 25 - 26.

 Approaches are ventilated efficiently with refreshing jets, except for one entry of the upper diagonal column located near the diagonal ventilation and filling furnace. The air stream worked out in each layer enters either a ventilation filling chamber or a diagonal ventilation filling furnace. From the fields in the layers near the top of the formation, the exhausted air stream to the ventilating gesenka additionally goes along the boundary ventilation and filling faults 27 - 28. In all the chambers between the faces of adjacent entries, mobile air regulators 29 are installed.

Sources of information:
1. Mashkovtsev I. L. Technology of underground coal mining. - M.: Publishing. UDN, 1982, p. 81.

 2. Burchakov A. S., Grinko N. K., Kovalchuk A. B. Technology of underground mining of stratified mineral deposits. - M .: "Nedra", 1978, p. 409-410.

 3. Burchakov A.S., Grinko N.K., Dorokhov D.V. et al. Technology of underground mining of stratified mineral deposits. - M .: "Nedra", 1983, p. 333-334.

Claims (4)

1. The method of developing a powerful flat bed with short faces in the diagonal layers, including conducting field preparatory workings, formation preparatory workings when cutting diagonal layers at an angle of 35 ^o to the horizontal and working off the diagonal layers in a descending order with a full laying of the worked out space, characterized in that each layer, after conducting field preparatory workings, the field is divided by the middle diagonal ventilation and filling furnace into the upper and lower parts, which are removed rams with a forward stroke and ramps with a reverse stroke in diagonal pillars located in the upper part of the field along the middle diagonal ventilation filling furnace, and in the lower - perpendicular to it, while the width of the entry is assumed to be 2.5 m and 2/3 of the volume of coal in half of the layers near the top of the seam, the excavation is carried out with gravity delivery of beaten coal to the conveyor sectional cross-turner and 1/4 of the volume to the conveyor cut, and in half of the layers near the soil of the coal, coal is additionally transported along boundary conveyor faults, cat rye placed on the soil formation.  2. The method of developing a powerful flat bed with short faces in the diagonal layers according to claim 1, characterized in that the driving of the tunneling machine into the chambers is carried out from gravity-feed delivery furnaces and conveyor cutting at natural obtuse angles of the diagonal pillars.  3. A method for developing a powerful hollow formation with short faces in the diagonal layers according to claim 1, characterized in that the delivery of people and equipment to the excavation fields is carried out along the horizontal horizontal output.  4. A method for developing a powerful shallow formation with short faces in the diagonal layers according to claim 1, characterized in that the outgoing air jets in half of the layers near the formation roof are additionally output along boundary venting-filling faults.

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