RU2233378C1 - Method for combined open-underground extraction of slanting coal beds set - Google Patents

Abstract

FIELD: mining industry.

SUBSTANCE: method includes, if mine is in upper portion of deposit, construction of slanting track, boring of vertical shaft and vertical venting wells. Set of slanting coal beds lying below the mine is opened by a group of mines, while vertical central-double shafts from mine bottom are driven, from the place closest to non-operating side of mine, for small depth, then from near shafts capital crosscuts up to upper bed are driven, after that for venting coal fields from earth surface central venting wells in empty rock are drilled, along slanting non-operating side of the mine up to exit of lowest bed of the set below the mine bottom, for venting slanting fields flange vertical venting shafts are drilled from the surface up to exit of lowest bed onto level of capital crosscuts.

EFFECT: rational use of open extraction, more effective operation with special-type coal deposits.

2 cl, 4 dwg

Description

The invention relates to the coal industry, and more specifically to open and underground coal mining and environmental protection.

There is a method of combined mining of a retinue of flat coal seams, in which the opening is performed by split horizontal trenches [1]. The disadvantage of the analogue of the method is only a partial participation in the combined mining of the overburden trench.

The closest technical solution to the method is a combined open-underground mining of a mineral deposit, in which under the working side of the quarry and its bottom an inclined opening ramp is used, which is used to deliver the mineral to the surface, and trunks and vertical ventilation wells are drilled for underground mining of the deposit [2]. The disadvantages of the prototype of the method are the presence of a long inclined ramp (or rather an inclined shaft), which will be subject to great deformation during operation, and the high cost of opening.

The basis of the invention is the task of creating a method of open-underground mining, in which the retinue of flat coal seams would be opened in the underground part most effectively using the existing quarry in the upper part of the field.

The essence of the invention lies in the fact that in the method of combined open-underground mining of a suite of shallow coal seams, including in the presence of a quarry in the upper part of the field, conducting an inclined exit, drilling a vertical trunk and vertical ventilation wells, the retinue of shallow seams lying below the quarry is opened by a group of workings at the same time, vertical central-twin trunks pass from the bottom of the quarry, from the place closest to the non-working side of the quarry, to a shallow depth, then from the roundabout yard major cross-hoses pass to the upper formation layer, after which centrally ventilated wells are drilled from the surface of the earth to ventilate the Bremsberg fields from the surface of the earth along the inclined non-working side of the open pit until the lower layer exits the formation below the open pit bottom, and vertical air flanks are drilled from the surface to ventilate ventilation wells until the lower reservoir reaches the level of capital cross-valves.

The essence of the invention also lies in the fact that at the level of capital cross-sections flank ventilation cross-sections pass from flank ventilation wells to the upper formation layer, and boundary ventilation faults pass in the wings of the sloping field on each layer.

As a result, sinking from the bottom of the quarry near its idle side when opening the lower part of the centrally dual vertical shaft to a shallow depth allows to reduce capital costs for vertical shafts and lifting along them.

Carrying out capital cross-valves from the near-barrel yard of the centrally-doubled trunks to the upper formation layer allows using them for coal delivery to the trunks, supply and exhaust of air from both fields.

Conducting ventilation wells drilled from the surface to the lower formation layer in the soil rocks of the open pit of the open pit at an angle of inclination and centrally assigned in the Bremsberg fields of the formation layers, as well as conducting flanking ventilation wells drilled from the surface to the lower formation layer at the level of capital crossovers, they allow you to effectively bring outgoing jets from Bremsberg fields directly and from sloping fields with the help of flanking ventilation taps that are on the same level as E crosscuts.

In general, the use of combined open-underground sequential development of a shallow coal seam suite with the opening of a layer of underlying formation by a group of workings makes it possible to rationally use open mining conducted at the outlet of the formation and to efficiently work out the underlying part of the coal field containing Bremsberg and deviated fields.

The proposal is illustrated by drawings.

Figure 1 shows the scheme of opening the suite of flat coal seams located below the quarry; figure 2 - gives a mining plan for the layers of the suite (conditionally there are three: m ₁ , m ₂ and m ₃ ); figure 3 is a horizontal section of the retinue at the level of capital cross-roads, aa; figure 4 - mining plan for the layers for sloping fields.

Figure 1 shows the quarry 1; a suite of shallow coal seams: 2 seam m ₁ , 3 seam m ₂ and 4 seam m ₃ ; opening vertical barrel 5; near-barrel yard 6; centrally-related inclined ventilation well 7 and major cross-hole 8.

Figure 2 shows Bremsberg 9, walker 10, lava 11 and 12 of the right and left wings of the mine field, retractable floor (or longline) drifts 13 and 14 of the field wings, ventilation drifts 15 and 16. The workings shown in figure 2 are similar in all Bremsberg fields of formation.

Figure 3 shows the ventilation flank wells of the wings 17 and 18 for the sloping field, the flanking ventilation cross-hoses 19 and 20 of the suite of the sloping field.

Figure 4 shows the slope with a walker 21, lava 22 and 23 of the wings; haulage floor (or longline) drifts 24 and 25; floor ventilation (or longline) drifts 26 and 27 behind the lavas at the border with worked out spaces, supplying additional air jets to the lavas floor (or longline) drifts 28 and 29, supplying additional air jets, boundary faults floor (or longline) drifts 30 and 31 for lavas at the borders with the worked-out space, boundary ventilation faults 32 and 33.

Figure 2 and 4 under the designation 34 shows the technological left pillars of coal.

The method is as follows.

At the bottom of open pit 1, on the border with the open pit, open pits 5 and a borehole 6 pass for underground excavation of a suite of formations m ₁ , m ₂ and m ₃ lying downstream of the pit, and then drill centrally assigned ventilation wells 7 in the rocks the non-working side of the quarry at its angle of inclination to output the outgoing air jets from the Bremsberg field and pass the major cross-roads 8. After that, the development of the Bremsberg fields of the suite begins. On each of the strata in the Bremsberg field there are Bremsbergs 9 with a walker 10, lavas 11 and 12 are cut in each wing and they are worked out in the presence of transport floor (or long) drifts 13 and 14, as well as ventilation floor (or long) drifts 15 and 16. Coal is delivered via Bremsberg 9 to the major cross-hole 8 and then to the near-barrel yard 6 and trunk 5. Outgoing air jets go through the floor ventilation (or longline) drifts 15 and 16 to the centrally assigned ventilation wells 7.

To prepare deviated fields, flank ventilation wells 17 and 18 are drilled from the surface to the lower formation suite at the level of capital cross-valves and flank ventilation cross-holes 19 and 20 are run at the field boundaries parallel to the capital cross-valves. Then, to develop sloping fields, lavas 22 and 23 are cut on each layer and cleaning operations are carried out in the presence of transport floor (or long) drifts 24 and 25, as well as additional air jets of floor (or long) drifts 28 and 29. The jets leaving the lava air flows along the floor drifts 26 and 27 left behind the lavas, and then air flows along the boundary faults 32 and 33 to the flank ventilation holes 17 and 18. The workings 31 and 32 left behind the lavas on this floor serve to supply air to stackable border with strikers 32 and 33 due to former split lava furnaces. Subsequently, in the underlying floor (tier), the excavations 31, 32 become supplying additional jets of air and ventilation.

The advantages of the proposed method for combined open-underground mining of a suite of flat coal seams are a significant reduction in the cost of opening the lower part of the field due to the small depth of the opening centrally doubled shafts and the passage from them of major cross-ditches, dividing the lower part of the field into Bremsberg and deviated fields; ensuring effective ventilation of the fields due to the drilling of centrally assigned ventilation wells in the Bremsberg field and flanking ventilation wells in an inclined field, as well as penetration of flanking ventilation crossings.

Sources of information

1. Elk I.N. Scientific basis of the combined development of coal deposits of the North. - Novosibirsk: Nauka, Siberian. Dep., 1991.-S.102-103.

2. Rylnikova M.V. Integrated development of ore deposits in a combined way. - Magnitogorsk: Publishing House of MSTU, 1998.-P.48.

Claims (2)

1. The method of combined open-underground mining of a suite of flat coal seams, including, in the presence of a quarry in the upper part of the field, holding an inclined ramp, drilling a vertical shaft and vertical ventilation wells, characterized in that the suite of flat coal seams lying below the quarry is opened by a group workings, while vertical central-twin trunks pass from the bottom of the quarry, from a place closest to the idle side of the quarry to a shallow depth, then pass from the borehole final crosshairs to the upper layer of the suite, after which centrally vented wells are drilled from the surface of the earth to ventilate the Bremsberg fields from the surface of the earth along the inclined non-working side of the open pit until the lower layer comes out under the bottom of the open pit, and for ventilation of deviated fields, vertical vertical ventilation holes are drilled from the surface wells until the lower reservoir reaches the level of capital cross-valves. 2. The method according to claim 1, characterized in that at the level of the capital cross-sections flank ventilation cross-sections pass from flank ventilation wells to the upper formation layer, and boundary ventilation faults pass in the wings of the sloping field on each layer.

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