RU2053307C1 - Method for creating setting split in permafrost rocks of mining face roof - Google Patents

Abstract

FIELD: mining industry. SUBSTANCE: method involves creating through setting split so that rock is completely broken along its formation line by providing through melting of rock massif along hole drilled from conveying drift to ventilation drift over coal layer in contact with roof. EFFECT: increased efficiency and wider operational capabilities. 1 dwg

Description

 The invention relates to the mining industry and can be used in underground mining.

 It is known that the economic efficiency of mining operations in mines depends primarily on the conditions for managing the roof, especially hard-to-collapse, which, as a rule, includes permafrost. Roof management, as the technological stage of treatment works, is one of the most responsible and time-consuming, directly related to the value of operational losses of coal ready for excavation in pillars for various purposes and mining safety. In this regard, the search for ways to facilitate the management of the roof and providing the possibility of its landing in predetermined places for the timely unloading of the supports of the working faces is of great economic importance.

 A known method of controlling the roof by creating weakened zones in front of the face line by thermal exposure to the rock mass. This method does not provide for breaking bonds between rock particles in weakened zones and therefore has insufficient efficiency, which is the main reason that hinders the widespread introduction of the method.

 A known method of forming a weakening gap in parallel guarded workings using blasting, used to protect the preparatory workings with a view to their reuse.

 This method of creating a landing gap is unacceptable for the conditions of the working face, since it requires a split furnace in front of the lava, and the undermining of the formation roof along the furnace to create a landing gap makes it impossible to transfer the production of mechanical supports. Thus, the implementation of this method of creating a landing gap in the face of the working faces is impossible due to deadlocks for mechanized roof supports.

 The technical result of the invention is the development of a method for creating a landing gap in permafrost rocks of the working faces by a continuous cut of the worked out rock console in predetermined places corresponding to the collapse step, without interfering with the working faces moving.

 This is achieved by the fact that the rock cantilever is cut to a predetermined depth along the well drilled at an angle to the face line from the conveyor to the ventilation drift along the coal seam at the contact with the roof by the heat flux on the rocks exposed in the well arch.

 The essence of the proposed method for creating a landing gap in permafrost rocks of the working faces consists in ensuring the conditions of thawing of roof rocks along the well by constantly supplying a gap-forming agent in the form of thermal air into its cavity, while the volume of the free zone in each well is regulated by periodically unloading thawed and collapsed rocks.

 Distinctive features of the proposed method for creating a landing gap in permafrost rocks of a working face roof is that it provides a through section of a worked-out rock console in predetermined sections of excavation fields without interfering with the face movement, the roof section is made by exposure to thermal air and feeding it into the face of the landing slot at all stages of its formation.

 As mentioned above, the known methods for creating weakened zones in front of the face line using the thermal effect, unlike the proposed method, do not include cutting roof rocks, but are based only on the softening of the massif when thawing, which reduces their effectiveness and inhibits widespread use.

 The technology of the proposed method is illustrated in the drawing, which shows the General scheme for creating a landing gap.

 Landing gap 1 is formed by thawing the roof rocks. Thawed rocks 2, having lost their adhesion forces, slide down and accumulate in the cavity of the well 3, through which warm air is supplied. The loss of adhesion forces by thawed permafrost is noted in known methods.

 Subsequently, as the slit face moves, the thawed rocks fill the gap cavity, limiting the bottomhole space.

 Thus, during the period of cutting a hole by thawing the rocks, the well throughout its length serves as a source of heat and a capacity for accommodating collapsed rocks.

 Wells flow in the direction from the conveyor to the ventilation drift along the coal seam at the contact with the roof, followed by the supply of thermal air through them until a gap is created in the roof of the seam along the line of contact with the well.

 Well drilling is carried out by a wood-boring machine of the SBM-ZU or LBS-4 type, which, when screwless drilling (on inclined and steep formations), provides a well length of up to 150 m, i.e. at a distance equal to the optimal length of the lava. When drilling on horizontal formations using augers, the possible length of the wells is 70-80 m. In this case, drilling of wells can be carried out from the conveyor and ventilation drifts towards each other until they fail to produce one continuous air channel. The diameter of the wells d according to the technical characteristics of the bore-resistant machines is 390, 500 or 800 mm. The ability to select the diameter of the well allows you to pass the gap in a more economical mode according to the conditions of air flow.

The well is drilled at an angle of ^about 2-5 to stope line, allowing a gradual transition gap longwall roof supports, and in such a way that in the upper arch of the roof of the well laid bare rock.

 With a positive thermal regime of the mines, when warm air is supplied to the lava through the falling drift, it is rational to drill wells and prepare the landing gap during the preparation of the excavation column before the start of treatment work. This will increase the stability of the working faces, and a section of the roof into blocks will reduce the parameters of the reference pressure zones.

 Warm air suitable for the well can be directed through it due to the shaft depression by installing an adjustable ventilation window 4 in the air drop. In those cases when the values of the shaft-wide (or district) depression in the wells are greater than its resistance to air movement, a ventilation window is installed in the wellhead to reduce unjustified air losses and ensure the necessary amount of air, which should maintain a positive temperature in the outgoing stream from wells, which guarantees the passage of warm air along its entire length.

 The necessary engineering calculations for adjusting the amount of air can be performed according to well-known methods and source data.

 Thus, with the positive thermal regime of the mines, the creation of landing slits along the drilled well line can be switched to automatic mode, ensuring the maintenance of the working window 5 in the bottom-hole part of the created landing slit in order to allow the passage of warm air along its bottom in the required amount. This condition is fundamental in the implementation of the proposed method. It is complicated by the dynamics of the process of creating a gap, when the face is removed as the rocks melt, and their sliding and collapse into the cavity of the falling hole, and then into the cavity of the slot itself, will inevitably lead to complete plugging of the well and the gap, and, consequently, to stop the formation process cracks.

When the well is completely cleaned and its cavity is kept in a free state, braking and stopping of thawing of rocks will also occur, since the air as a coolant will leave the well as along the line of least resistance without washing the bottom of the gap. Therefore, in order to create a landing slit, and even more so for carrying out these works in an economical mode, it is necessary to maintain the working window in the bottom-hole part of the slit in optimal dimensions, which should ensure economical air consumption with a maximum penetration rate. This value of the optimal air flow Q _optim is determined according to practice. The criterion for its evaluation is the presence of air coming out of the gap and its positive temperature value.

The determination of the amount of air passing through the borehole, and later on along the bottom-hole part of the gap, consists of two measurements: before the bridge with the window Q (m ³ / s) and behind it Q ₁ (m ³ / s). Then Q _well QQ ₁ m ³ / s. The measurement technique is known.

 The sequence of work on the sinking of the gap is as follows.

 After drilling the well, the drill string is removed with a sweep of its cavity. Then warm air is supplied and the formation of a gap begins. Thawing of the rock gradually fill the well, catching up with the bottom of the gap. With a reduction in air flow, which is established by measurements, as indicated above, the well is cleaned with a boring-resistant machine. In this case, a drill bit of smaller diameter is used than when drilling a well, for example, from a drill rod with a diameter of d 160 mm, used in open cast mining. A smaller diameter will allow you to more accurately adjust the area of the bottom-hole working window. After the first cleaning of the well, drill string 6 remains in it until the slot is drilled to the design depth.

 In the future, monitoring the gap penetration consists in measuring the amount of air passing through the gap and maintaining its amount within the optimal value. With a decrease in air consumption, the drill string is connected to the burst and a rock is discharged from the cavity of the well that exfoliated during thawing in the bottom of the slot. Due to the issuance of rocks from the well, the rocks that fill the cavity of the gap settle, increasing the area of the working window.

 When reaching the air flow within the optimal values, the delivery of rocks from the well stops. In the future, the process is repeated.

 As the gap depth approaches the design elevation, the drill string is removed. The borehole and the gap are podbubitsya, as the process of penetration continues, and when the design depth is reached, it is completely isolated by settled rocks. As the lava approaches, the drilling diameter of the working diameter is reintroduced into the well, i.e. the diameter over which the well was drilled. The rocks are removed in order to avoid dilution of the coal during the passage of the slit by the face.

 A sufficient depth of the landing gap may be a depth equal to the thickness of the removed formation. In this case, collapsing rocks within the cut-out layer, filling the space behind the lining, pile up the overlying rocks by loosening and, perceiving the load from their weight, unload the lining of the working face.

 In the negative thermal regime of the mine, local air heating can be applied directly in the wellhead by installing an electric air heater.

 If it is necessary to speed up the thawing process, it is possible to use a local ventilation fan to pump air into the bottomhole space of the slot.

The distance between the landing slots (between the wells) is set in accordance with the calculated or actual collapse step L _arr and can be adjusted based on specific conditions, bearing in mind that the determining factor for the created step of the roof landing is the permissible load limit on the lining of the working faces, which in all cases should not exceed this limit.

 The adopted technology of preliminary preparation of landing slots eliminates the violation of the rhythm of the lava due to possible delays in their preparation. However, a joint option is not excluded, when the landing cracks are prepared in front of the lava in the process of cleaning. In this case, we apply the forced method using local ventilation fans and heated forced air.

 The depth of the landing slit can be determined by a measuring pole from the preparatory development.

 The preparation time for the landing slit can approximately be determined according to the practice of mining landfills in placer deposits with layer-by-layer excavation of thawing rocks. Experience shows that in this case the thawing depth reaches up to 1.5-2 m per month.

 The danger of coal self-heating when air is supplied to a well drilled over a coal seam is eliminated, since in this case there are no destroyed and loosened masses of coal in the volumes of its critical values of about 5 tons, and the monolithic surface of the well drilled in its entirety has sufficient air resistance, interfering air filtration deep into the reservoir. The evidence of this is the practice data, where during formation preparation many kilometers of the coal surface are exposed, and there are no foci of self-heating. They, as a rule, arise in places limited by heat exchange conditions and contributing to its accumulation. This technology is not associated with these factors.

Claims (1)

 METHOD FOR CREATING A PLATING SLIT IN PERMANENTLY FROZEN ROCKS OF REDUCING BOTTOMS, including drilling of leading wells from the conveyor to the ventilation drift at an angle to the bottom line along the coal seam at the contact with the roof, introducing a gap-forming agent into the borehole, characterized in that they constantly inject warm air and regulate the volume of the free zone in each well by periodic shipment of thawed and collapsed rocks.

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