SU1710746A1 - Method of working protection - Google Patents

Abstract

The invention relates to mining and improves the efficiency and cost-effectiveness of protecting the mine. On the seam coal 1 with breaking of weak rocks (P) of soil 3 passes t drifts (W) 4. Lava is located between W 4. From W 4 P of the soil the drill of well (C) 9. Orient C 9 parallel to the reservoir. Before charging with the C e, in parallel with the protected W in the developed space, metal wedge 11 is installed with a thrust between the roof and the soil, wedge 11. Then charge 09 and blow it up. Simultaneously with the ejection of P, metal wedges are thrown out, which, embedded in the roof P and form a crack in it 14. Along the line of the crack unloading of the rock mass from high stresses occurs. 1 tab., 3 ill. ^ 4 ^ O)

Description

The invention relates to the mining industry, in particular, to the protection of underground workings in the development of seams with hard-to-break roof rocks.

There is a method of protection of preparatory development, in which slits are cut into the roof of the formation.

The purpose of the invention is to increase the reliability of the protection of the preparatory mine when mining a coal seam. .

The essence of the method lies in the fact that along the contour of the protected excavation from the side of the worked-out space, on the border of which the excavation is carried out, gaps behind the sections of the mechanized support are cut in the roof and the soil of the formation. Cutting slits insert triangular concrete cross-section beams and, with the help of hydro-rails, press the beams into the slits in the roof and soil, causing an increase in stress concentration and destruction of the rock mass by cracks. To enhance the destructive effect before pressing the beams into the slots, additional thrusting is provided to several sections of powered roof supports located near the protected excavation. After that, re-press the cutting beams into the cracks, and then remove the additional thrust of the hydraulic sections of the lining. It is assumed that when re-spreading the roof mechanical sections will be raised, and when removing the thrust from the roof mechanical sections it will fall onto the cutting beams,

In the future, the hydraulic posts are replaced with wooden stands. After replacing all hydro stands with wooden ones, a protective strip of hardening material 1a is erected, wooden stands in the protective strip are made of monoliths.

The main disadvantage of the method of guarding preparatory generation is that there are no machines for cutting cracks in hard-to-break hard rocks of the reservoir under development. The second disadvantage is that when cutting gaps in a hard-to-break roof and low-strength soil, it is impossible to introduce cutting concrete beams into the roof, since the roof is several times more durable, it is not destroyed by the cutting beam. The beam is pressed only into slots cut in the soil.

Since the beam does not penetrate a strong, hard-to-crush roof, the fracture of the roof does not occur. Thus, the application of this method does not ensure the achievement of a positive effect in the development of a reservoir with hard-to-destroy blood lines. ,

The closest in technical essence and the achieved result is the method of roof control in the development of flat coal seams.

The purpose of the invention is the separation of sewage treatment works and roof management works and increase of management efficiency.

The essence of the method lies in the fact that in the excavation column prepared by the workings completed with the lower undermining of rocks, deep wells are drilled in the soil of the reservoir parallel to the clearing face and the soil surface, they are charged with explosive materials and blown up. Due to the explosion of the charges in the soil, the rocks loosen and a rock band is formed from the explosives dumped into the developed space of the rock of the sleeping rocks, Preventing the collapse of the roof behind the bottom hole of the lava and near the mine

The main disadvantage of the protection of 6qTKM rock strata formed by the explosion is that the strip causes the hard-to-break roof rocks to hang over the developed lava space. Due to the formation of rock cantilevers hovering over the developed lava space, an elevated bearing pressure is created at the edge of the coal massif. Under reference pressure, weak rocks. (The soils of the workings and the side walls of the workings are deformed, which entails the destruction of the roof supports.

The process of deforming the development takes a long time, since the rock cantilevers hovering over the developed lava space do not collapse spontaneously. In addition to this drawback, it is very difficult to drill long, well-directed wells over soil rocks because of their curvature during drilling.

Thus, the protection of workings by rock bands formed by the explosion of charges in long wells is inefficient, and the strip technology is very difficult because of the difficulties of drilling long, well-directed wells. The aim of the invention is to increase the efficiency and effectiveness of the method of protecting the production of rock according to Losya, formed by loosening | weak soil rocks by explosive energy | of charges in short wells. The goal is achieved by the fact that the method of guarding the development of a rock strip, including carrying out generation, processing of lava, drilling wells in the soil, charging and blasting charges in them, is different in that before blasting charges in the wells near the mine, an organ lining and metal wedges with a thrust between the roof and the soil of the layer along the development parallel to its axis from the side of the developed space, and then explode charges in the wells with the formation of a longitudinal crack in the roof to break it. Installation of rigid bases on the reservoir; Installation of wedges with a space between the roof and a rigid base; introduction of wedges into the roof with explosive energy; the formation of a longitudinal crack in the roof, the collapse of the rock roof console are essential distinctive signs that ensure the achievement of the goal. FIG. 1 shows the protection of workings by rock bands formed by an explosion, general view; in FIG. 2, section A-A in FIG. one ; in fig. 3 section bb in fig. 1. Example The application of the proposed method is considered in relation to the development of a 1.0-1.2 m hollow nJiaCta 1, in the roof of which there is a hard-breaking threshold 2 and a thickness of 2-3 m, and in the soil 3 clay of low strength. On a seam of 1 coal with undercut cjrabyh, rocks of the soil 3 lead drift. Lava 5 is placed between the drifts. When lava 5 moves over the developed space behind it, the working rock of the roof 2 hangs to form rocky cantilevers 6, the length of the cantilevers 6 is equal to .15–20 m (according to well-known literature). With an increase in the hard-to-crush thickness of the roof 2, the length -1 -1 66 hovering coisols 6 increases. The hang over the developed space behind the lava 5 rock consoles 6 Remains for a long time, since they do not collapse spontaneously. Due to the presence of rocky cantilevers 6, the stress state of the marginal portions of the coal seam 1 massif near the workings increases by a factor of 2-3 compared with the initial stress state. The extension of the edge part of the 7-COAL array with an increased voltage is 20–50 m and depends on the specific conditions of development (Fig. 3). Production 1 in the area behind lava 5 is protected by rock bands 8. For formation of rock bands 8 from wells j, wells 9 are drilled through weak rock 3. Wells 9 are oriented parallel to formation 1 or horizontally (Fig. 1 and 3). The thickness of the rock layer being exploded, i.e. the distance from the well 9 over the soil surface 10 of the coal seam is 1.0-1.2 m. During the explosion of charges in the wells 9, the rock 3 loosens up in volume 1.8-2.0 times, is ejected upwardly by the explosion energy and fills the developed space up to the roof 2 of the reservoir 1 in the area equal to the explosive length of the well 9. When the formation’s instability t changes the thickness of the explosive layer of the soil 3 rock, so that the loosened and increasing in volume of the rock fill the space . The length of the well 9 is taken into account so that the width of the rock strip 8 is not less than 2 9.6 m, where, 2 m is the formation thickness. The borehole diameter is 75 mm. The explosive consumption per well is 3 kg, the distance between the wells is 1.2 m (calculation of the parameters of drilling and blasting operations is attached). The explosive materials are charged and the wells 9 located behind the hole 5 blow up (Fig. 1). At the same time, two or three wells are blown up so that the lagging behind the lava 5 of the rock strip formed by blasting charges in the wells 9 does not exceed 5 m and meets the requirements of the Safety Rules. .7 .1 Creating a rock strip by loosening rocks by explosions of charges in wells is much more economical compared to laying out the rubble strip by machine or manually. Behind the face 5, in the developed space, prior to charging the wells 3, in parallel with the protected excavation 4, metal wedges 11 are installed with a thrust between the roof 2 and the soil 3 of the reservoir 1 (Fig. 1). When the soil is watered, a rigid base 12, made in the form of a reinforced concrete block or a channel section, is placed on its surface 10, and then metal wedges are installed between the roof 2 and the base 12 with a metal wedge 1 Metal wedge 11 is made from a flock of rails that are pointed with one side or length of a pipe with a diameter of 0.08-0.1 m, pointed on one side and filled with concrete for strength. The wedge 11 is installed along the guarded excavation at a distance of 23 m from the support. The distance between the wedges in the row is 0 ,, m. The installation of the wedges 11 with a thrust between the roof 2 and the soil 2 is carried out under the protection of a wooden organ crepe i pi 13 installed at a distance of 1.5-1.7 m from production 4. Krep'13 serves as a cutting row and limits the spread of loosening of soil rocks 3 when charges explode in wells 9 (Fig. 2). When charges explode in wells 9, soil rock 3 loosens and is released by explosive energy upwards to the side of the roof 2. A rock band 8 is formed. Simultaneously with the ejection of the rock, metal is thrown out skie wedges 11 under the influence of Wuxi whether from the hard base 1 wedges 11 are embedded in the rock roofings 2 to a depth equal to 1 / 2-1 / 3 of its cardinality with the speed progression ejection equal to 50-60 m / s. To introduce metal wedges into a solid rock of the roof 2, the charge value in well 9 was increased by 1.8 kg (the calculation of the required mass of the charge for introducing metal wedges into the hard-to-wear roof rock is attached). The mass of charge per well is 6.1 kg. When metal wedges 11 are introduced into the hard-to-break rock 68 of the roof 2 at a speed of 50-60 m / s, the roof rock 2 is destroyed due to stretching deformations - and a portion of the destroyed roof rock 2 WY is thrown into the worked-out space. With this interaction of metal wedges with the roof, a crack 14 is formed in the latter (Fig. 3). / 4l, the formation in the Korli rock 2 of a continuous crack 14, oriented along the mine 4, the distance between the wedges 11 in the row is assumed to be 0.3-0.4 m. The crack 14 formed in the hard-to-break roof rock softens the roof . When the lava 5 leaves the fracture 14 formed in the roof, it hangs 5–6 m above the discarded area of the lava 5, the cantilever 6 collapses along the crack line 14. After the hinged cannon detaches along the artificial crack 14, the short rock console 15 hangs over the developed space behind the lava 5. The length of this console is 3 4m, Tie. the length of the conso / / and decreases by a factor of 3-4 (Fig. 2). After the formation of a short cantilever 15, the length of the reference pressure zone and the concentration of stresses in it are reduced to m (1Least level 16. There is therefore a discharge of rock mass 7 from high stresses. The discharge factor of the massif is 1.5-2 (Calculation of the value of the array unloading factor is attached.) The weak rocks of the soil 3 are not destroyed or swell under the influence of reduced stresses. Thus, the unloading of the rock massif provides an increase in the efficiency of excavation 4, h This is expressed in reducing the deformations of their walls and soil by reducing the deformations of the workings 4, reducing their cross-sectional area by 10 to 15 when they are carried out. This increases the cost-effectiveness of the protection method by 2025%. In addition, by reducing the contour displacement the support in the supported workings reduces the cost of maintaining them. The use of the proposed method of protecting the development of a rock strip formed by the explosion of the rocks of the formation’s soil with the simultaneous softening of the hard-to-crush roof due to introducing into the rock to a depth equal to 1 / 2-1 / 3 of its thickness, metallic wedges with explosive energy, reduces the cost of protecting the mine by reducing the cost of forming a breed of strip and also by reducing the cost of carrying out mining, Fo r MULAI 3 ABOUT AREA Method of protection of development, including the mining of lava, drilling wells

Proposed

Carrying out development; Carrying out development.

Lava mining

Drilling wells in the soil of the soil precedes the passage of lava Installation of rigid bases on the soil of the reservoir

Establishment of wedges with cross-section between roof and rigid base

Installing an organ support. Exploding wells behind the slab, creating a strip. Introducing wedges into the roof with explosive energy.

Formation of a longitudinal crack in the roof

The collapse of the breed roof console C

Famous

Famous

Testing of the extraction column by lava Drilling of wells into the soil before the approach of lava

Blasting holes after lava pass

Preventing Collapse of the Roof

Advancement of mechanized roof supports

Cutting gaps in the crawl and soil

Inserting cutting beams into the slots An additional breakdown of sections of the reinforcement Repeated pressing of the excavation into rock. Soils, loading and blasting of explosive charges in them, so that, in order to increase the efficiency and cost-effectiveness of the protection of mine Before the charges are detonated in the wells, in the lava along the mine, metal wedges are installed with their thrust between the roof and the soil, and then explosive charges are blown up in the wells.

17107A612 ... "..---

Way

t Famous

Proposed

Table Continuation

I I -vFamous

cutting beams in the gap Removing additional strut of mechanical support brackets Replacing hydraulic posts Erection of a guard strip

Fmg i

Claims (1)

Formula s A method of protecting a mine, including lava mining, drilling wells from a mine into a rock. Soils, loading and blasting explosive charges in them, heating and blasting with the fact that, in order to increase the efficiency and profitability of protecting the mine, metal wedges are installed in the lava along the mine before blasting the charges in the wells along the mine, spreading them between the roof and the soil, and then explode. explosive charges in wells. Way Offered | Famous] Famous Carrying out work Lava mining Drilling boreholes in the soil rock before the passage of the lava Installation of rigid bases on the soil of the formation Lava excavation column drilling Drilling wells into the soil before the lava approach Drilling of wells in a collapsible roof of Nyev with a gap between the roof and a rigid base Installing the organ support -_ Blasting of wells Blasting of wells behind the face of the head, after the passage of lava, creating a strip The introduction of wedges -_ in the roof with the energy of an explosion The formation of pro-longitudinal cracks in the roof Collapse of the rock-roofing console “- Prevention of collapse of the roof. Mechanized lining sections promotion Cutting gaps in the roof and soil Pressing into the slits of the cutting beams ’ Additional spacing of the sections of the reinforcement Repeated pressing 11 1710746 12. Continuation of the table ί ί g .1———————— _; U .----— -, - Method Known Cutting Beams in the Slit ' Removing additional spacing of the mechanical support lining Replacing the hydraulic struts Fmg. 1