RU2459079C1 - Method for developing area of flat and slope seam liable to rock-bumps - Google Patents

Abstract

FIELD: mining. ^ SUBSTANCE: extracted core of expendable wells helps to define the outline of bed pinching-out at the area, inside the outline the limits of its standard power are registered and on the base of their average position of seam strike the contoured workings are passed. First cuts are located perpendicular to contoured workings upslope or down-dip and till the outline of bed pinching-out and separate the area to paired blocks. Beginning from the end of each paired block and by moving the front line of extraction by reverse movement there are adjacent extraction workings going from the first cuts to both sides with axes shift and parallel to contoured workings; adjacent extraction workings help to extract the bed selectively and are performed with ground and roof breaking, between the paired blocks there remained are solid blocks with width not more than 10% of abutment pressure zone. Each paired block has formed groups of under-goaf and one support solid block. During seam extraction there drilled are prognostic holes and control the degree of rock-bump hazard is performed, if it is revealed the support solid blocks are unloaded. ^ EFFECT: increase of safety of developing the area of flat and slope seam liable to rock-bumps and reduction of mineral product losses due to involvement of bed pinching-out areas into actual mining. ^ 3 cl, 3 dwg

Description

The invention relates to mining, and in particular to a technology for the development of shallow and inclined shock hazardous formations prone to geodynamic phenomena in areas of limited conditioned power up to wedging.

There is a known method of developing the Starobinsky salt deposit with inter-chamber and block pillars (see Permyakov RS, Proskuryakov NM Sudden emissions of salt and gas. L., Nedra, 1972, p. 49-52). According to this method, mine fields of potash mines are divided into panels and half-panels by ventilation and transport drifts, and half-panels are divided into blocks by transport and ventilation block drifts. The extraction of salt in the blocks is carried out by chambers with the loss of inter-chamber pillars, the change in width of which supports their smooth deformation and destruction with the prevention of critical pressure on the roof. This method provides control of the roof by reducing stresses and pliability of the pillars in it with a gradual decrease in the strain rate. However, the main disadvantage of this method is the lack of control over the limiting span of the roof during intensive destruction of the inter-chamber pillars, which on the shock-hazardous formation is associated with intensive loading onto the inter-block pillars and their subsequent destruction in geodynamic form.

There is a method of developing formations with a chamber-and-pillar system with holding cameras and leaving inter-chamber pillars (see L. Shevyakov, Development of mineral deposits, M-L., Ugletekhizdat, 1953, p. 400-402). In this method, chambers are separated from drifts by chambers separated from each other by inter-chamber pillars, which are then worked out in reverse by sunset, and the width is selected from the principle of excluding loads from roof pressure based on the calculation of the weight of the rocks above the set of natural equilibrium. The method allows you to remove the formation with a reverse movement of the faces and control the roof. However, the disadvantage of this method is the lack of an assessment of the state of the roof as the worked-out space grows when excavating pillars by sights. In a shock-hazardous formation, the lack of control over the influence of the length of the worked-out space affects the emerging stress concentration on the supporting and boundary parts of the formation, and the extraction of pillars by sunset without limiting geometric parameters entails the formation of foci of geodynamic phenomena and their direct manifestation, therefore, the use of the method for developing shock-hazardous formations is ineffective.

The closest in technical essence to the claimed method is a method for developing coal seams with short faces by a chamber system with barrier pillars (see the Methodological Guide for the selection of geomechanical parameters of technology for developing coal seams with short faces, St. Petersburg, VNIMI, 2003, p.6-15 ), adopted for the prototype, including the sinking of the contouring cutting and excavation workings, maintaining the stability of the site pillars, determining the width of the zone of reference pressure and control the category of shock hazard. According to this method, drifts of the main direction pass to the boundaries of the mine field and panels are worked out from them in successive stripes, for which a group of parallel chambers pass, which partially remove the formation. Inter-chamber pillars are left between spent chambers and the worked-out space is maintained either by their group leaving in the panel section, or with the additional leaving of pillar barriers, which periodically alternate with a group of interchamber pillars. The method allows to extract significant coal reserves in conditions where high-performance lavas are ineffective in terms of bedding associated with a limited length of sections, their complex configuration and variability in thickness, and the presence of geological disturbance.

The disadvantage of the method in the variant of only inter-chamber pillars is the difficulty in determining their optimal number in the section and establishing geometric parameters in the section, leading to group destruction in large areas with uncontrolled collapse of the roof, entailing geodynamic manifestations of rock pressure on the shock-hazardous formation. In the variant of leaving the group of interchamber and barrier pillars under unstable conditions, for example, in terms of thickness or area of the formation, there is no justification for the optimal distance between barrier pillars, and calculations of the geometric dimensions of pillars based on the principle of balancing the effective load and their bearing capacity under such conditions from - due to fluctuations in the level of loading, they have significant errors due to inconsistencies with the actual geomechanical state of both pillars.

These disadvantages of the method create the provocation of uncontrolled destruction of the pillars with geodynamic manifestations and subsequent uncontrolled collapse of the roof in already used chambers and directly in chambers where coal is being extracted. The development of sections of a shock-hazardous formation with restrictions on conditional power with a transition to wedging out due to their unevenness and incontinence is more sensitive to convergence of the roof and soil, the requirements of justifying the functional signs of preparing the blocks and orderly leaving the pillars of reasonable geometric dimensions, therefore, the direct application of the options for this The method in these shock hazardous areas is inefficient.

The claimed method solves the problem of safe excavation of sections of a shock hazardous formation that have limitations on conditioned power with a transition to pinching, where long high-performance treatment faces are unacceptable.

The technical result obtained from the use of the claimed method is to increase the safety of mining sections of gentle and inclined shock hazardous formations and to reduce the loss of minerals due to the involvement of sections of its pinching out into the treatment recess.

The specified technical result is achieved by the fact that in the method of developing a section of a shallow and inclined shock hazardous formation, including sinking contouring cut and excavation workings, maintaining the stability of the section with pillars, determining the width of the reference pressure zone and controlling the shock hazard category, according to the invention, the contour is determined from the extracted core of exploration wells the wedging out of the formation in the area is recorded inside the contour of the boundary of its conditioned capacity and according to their average position over contouring workings extend from the formation extension, from which perpendicular to them upward or downward and to the formation wedging contour, split workings pass and divide the section into paired blocks, then, starting from the end of each paired block and with the front of the excavation moving backward, from the split workings on both sides with displacement of the axes and parallel to the contouring workings, adjacent excavation workings separated by pillars are used, which selectively extract the formation and which pass with soil or roof erosion formation, leave between the paired blocks of pillars with a width of not more than 10% of the zone of reference pressure, and in each pair of blocks form groups of sub-gate and one reference pillar. In this case, the sub-gate pillars leave a width of no more than 10% of the zone of reference pressure, and the support pillars are formed with a width determined from the condition of maintaining a stable deflection of the main roof with a length of not more than 80% of its maximum span. Paired blocks work out to guard pillars, which form a width of at least 50% of the zone of reference pressure and leave along the contouring workings. At the same time as the formation is removed from the excavation openings, forecast holes are drilled into the sides of the support pillars and the volume of drill trifle output is measured, which determines the degree of impact hazard, and if a dangerous category is detected, the support pillars are unloaded to a non-hazardous category, for example, by drilling with unloading wells.

The method is illustrated by drawings, where Fig. 1 shows a diagram of mining a section of a shallow and / or inclined shock hazardous formation having restrictions on conditioned power with a transition to wedging; figure 2 shows a cross section across the strike of the formation with a profile of the sequence of penetration of the workings in the fall and leaving the sub-gates and supporting pillars; figure 3 in the context of the support pillar shows the oncoming drilling of its forecast holes and unloading wells.

The method is carried out in the following sequence.

During exploratory drilling of coal reserves in the formation 1, the contour 2 of the formation 1 is determined from the extracted core cores, the boundaries 3 of its conditioned capacity are recorded inside the contour 2 and the contouring workings 5 pass from it along the strike of the formation 1 from the nearby transport workout 4, from which they are perpendicular to them in the uprising (with the contour on the opposite side - in the fall) and to the contour 2 of the wedging out of the formation 1, there are split workings 6 and they divide the section into paired blocks 7.

Starting from the end of each paired block 7, a partial excavation of the formation 1 is carried out with the front moving backward (in Figures 1 and 2 are shown by arrows), for which adjacent excavation openings 8 pass from the cutting workings 6 to the contouring workings 5 parallel to them. They extend in both directions from split workings 6 and with displacement of the axes. Mining excavations 8 layer selectively extracted, if their height exceeds the power of the wedged out layer 1, and in the roof or soil, the rock mass is opened, which is extracted individually with an undermining. Excavation openings 8 extend half the width of paired blocks 7, which is taken from the condition of effective range of coal scraping to split openings 6. Between adjacent paired blocks 7 at the ends of the excavation openings 8 leave a bed of the formation in the form of an extended pillar 9 with a width of not more than 10% of the reference zone pressure, which is determined by the nomograms of instructional documents for the depth of development and reservoir power 1.

Excavation workings 8 pass with the formation of groups of sub-winding 10 and one supporting 11 pillars. Sub-gate pillars 10, similarly between-block, leave a width of no more than 10% of the support pressure zone so as not to carry out additional unloading measures for them, and support pillars are formed with an increased width, determined from the condition of maintaining a stable deflection of part of the main roof with a length of not more than 80% of its maximum span, which is established by experience in the development of the reservoir in areas of conditioned power or calculated by the strength, power and structural attenuation of the roof. Paired blocks 7 are developed to guard pillars 12, which are left along the contouring workings 5 in accordance with the guidelines for the sustainable maintenance of stationary preparatory and capital workings. In this case, the security pillars 12 form a width of at least 50% of the zone of reference pressure.

According to the shock hazard conditions of the developed formation 1, at the same time as it is partially removed from the excavation workings 8, forecast holes 13 are drilled into the sides of the support pillars 11 and the volume of drill trifle output during drilling is measured, which determines the degree of shock hazard. If a dangerous category is found, support pillars, for example, are drilled with oncoming discharge wells 14 with overlapping ends and an interval for providing a non-hazardous category.

The development of a shallow and inclined shock hazardous formation section of the claimed method allows its safe excavation in places that have limitations in conditional power with a transition to wedging out, and to involve parts of the mine field that are classified as losses when working with high-performance lavas under geological conditions. The preparation of the mine field section, including the sinking of contouring, cutting and excavation workings with the formation of paired blocks, provides for the widespread extraction of the formation within the mine field with restrictions on the conditioning capacity.

The width of the pillars between paired blocks and between adjacent excavation openings, limited to 10% of the zone of reference pressure, is a condition for acquiring compliance by such pillars up to a quiet smooth destruction after excavation of the formation under fluctuations in rock pressure. At the same time, the width of the pillar pillars, calculated from the condition of stability of a part of the main roof with a length of not more than 80% of the maximum span of the roof, maintains safe maintenance of excavation workings during extraction of the formation from them, and the forecast and discharge drilling of pillars excludes the formation of geodynamic foci in them phenomena. Conducting work with paired blocks perpendicular to the contouring mine workings and displacement of the axes adjacent to the semi-blocks and excavation blocks with their parallel contouring creates a uniform distribution of loads over the area of the development site, taking into account the limiting spans of the roof and loads on the supporting and sub-pillar pillars. Security pillars with a width of not less than 50% of the reference pressure zone along the contouring workings make it possible to ensure uninterrupted transportation of coal from the development site and protect it from the effects of mining in adjacent sections of the mine field.

This embodiment of the method extends the boundaries of the extraction of shock hazardous formations with geological conditioning restrictions while ensuring the safe conduct of treatment works to prevent geodynamic phenomena and maintain the stability of the workings. Compared with the prototype, maintaining the intervals between the groups of sub-bearing and supporting pillars, linked to the limiting span of the roof, predictive and unloading control in them of the shock hazard category and systematic geometric preparation of sections of the mine field with geomechanically justified dimensions and sufficient bearing capacity of the pillars with the flexibility of the substrates provide the exception of the formation of centers of shock hazard with its implementation in the form of geodynamic phenomena and caused by uncontrolled collapsed roof at the development site.

Claims (3)

1. A method of developing a section of a shallow and inclined shock hazardous formation, including sinking of contouring cutting and excavation workings, maintaining the stability of the site by pillars, determining the width of the reference pressure zone and controlling the category of shock hazard, characterized in that the contour of the formation wedging out on the site is determined by the extracted core of exploration wells, register within the contour of the border of its conditioned capacity and contouring workings pass along their average position along the strike of the formation, about of which perpendicular to them in an upward or downward direction and to the contour of the formation wedging out, there are split workings and they divide the area into paired blocks, then, starting from the end of each pair of blocks and with the front of the excavation moving backwards, from the split workings in both directions with axes shifted and parallel to the contouring workings, adjacent excavation workings separated by pillars pass, which selectively extract the formation and which pass with undermining of the soil or the roof of the formation, leave pillars wide between paired blocks e more than 10% of the zone of reference pressure, groups of sub-gaps and one support pillar are formed in each paired block, while pillars are formed with a width determined from the condition of maintaining stable deflection of the main roof with a length of not more than 80% of its maximum span, paired blocks work out to the guard pillars, which are left along the contouring workings, at the same time as the formation is removed from the excavation workings, forecast holes are drilled into the sides of the support pillars and the volume of drill trifle output is measured, according to which they control the degree of impact hazard, and when its dangerous category is detected, the support pillars are unloaded to a non-hazardous category, for example, by drilling with unloading wells. 2. The method according to claim 1, characterized in that the sub-gate pillars leave a width of not more than 10% of the zone of reference pressure. 3. The method according to claim 1, characterized in that the security pillars form a width of at least 50% of the zone of reference pressure.

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