RU2454540C1 - Rock pressure control method - Google Patents

Abstract

FIELD: mining.

SUBSTANCE: method includes driving of development-temporary workings, working off of primordial chambers of tapered section, their filling with curing mixture forming artificial pillars, formation of massive ore pillar between artificial pillars. Rock pressure is reallocated on artificial pillars. Touchdown working is driven along ore pillar symmetry axis by contact with ore deposits in overlying roof rocks. Blasting wells are drilled from it radially within outlines of natural arches so that ends of these wells most accurately form sizes and surface of line of natural arches in compliance with estimated ultimate strength of overlying rock massif. Complete discharge of massive ore pillar is performed by induced caving of roof rock between artificial pillars on chambers expanding upwards, support of artificial pillars by caved rock is provided. Massive ore pillar stocks are developed with support of overlying roof rock by natural arches resting upon artificial pillars and retaining slopes formed near side surfaces of artificial pillars during loading of broken ore.

EFFECT: increasing reliability of rock pressure control and labour safety.

2 cl, 4 dwg

Description

The technical solution relates to the mining industry and can be used to control rock pressure during underground mining of horizontal and flat ore deposits.

There is a known method of controlling rock pressure (USSR AS No. 998759, E21C 41/06, published in BI No. 7, 1983), including maintaining overburden with ore and artificial pillars from a hardening tab, rock collapse and mining of the excavation section with cameras with redistribution rock pressure on artificial pillars, and in the center of the excavation site, a massive ore pillar is left, and after mining the entire site, chambers are placed on both sides of it, and then a massive pillar is excavated.

The disadvantages of this method are the loss of ore in interchamber ore pillars, the possibility of dynamic manifestations of rock pressure during the destruction of these pillars by the pressure of overlying rocks and the likelihood of air strikes on working horizons during self-collapse of roofing rocks, which negatively affects the safety of underground workers.

The closest in technical essence and the set of essential features to the proposed technical solution is a method of controlling rock pressure (USSR AS No. 1606667, E21C 41/16, published in BI No. 42, 1990), including maintaining overlying rocks with artificial pillars from a hardening mixture, the formation of a massive ore pillar between artificial pillars during ore excavation and the redistribution of rock pressure on artificial pillars by mining reserves of a massive ore pillar and the collapse of roof rocks, with artificial pillars and the central part of the massive ore pillar is first loaded with chambers of its edge parts with artificial pillars, and then the massive ore pillar is completely unloaded by forced collapse of the roof rocks between the artificial pillars onto the formed chambers, while the artificial pillars are supported by the collapsed rocks, and then they are fully worked out reserves of massive ore pillar with formation of retaining slopes at the side surfaces of artificial pillars.

The main disadvantage of this method is the high indentation of the workings of the roofing rocks over artificial pillars from the hardening mixture, which creates an increased concentration of stresses around these workings and the likelihood of dynamic manifestations of rock pressure in the workings during work on the forced collapse of overlying rocks. In addition, the location of the workings above the artificial pillars of the hardening mixture does not allow you to accurately reproduce the contours of the arch of the natural balance of rocks over the massive whole ore.

Mining practice shows (Kartoziya B.A., Borisov V.N. Engineering tasks of the mechanics of underground structures: Textbook. 2nd ed., Revised and supplemented. - Moscow: Publishing House of the Moscow State Mining University, 2001, p.12 ) that the arch of natural equilibrium in rocks is usually formed by a parabolic surface. The height h of the arch of natural equilibrium depends on the ultimate strength of the rocks.

When implementing the known method of controlling rock pressure, a roof with a tent-like shape is formed in the overlying rocks, which is formed by flat side surfaces and is not a true set of natural equilibrium. This can lead to self-collapse of rocks over a large area until they reach the true form of the arch of natural equilibrium and, as a result, to air strikes in the workings.

Thus, the insufficiently accurate formation of the arch of natural equilibrium in the overlying rocks does not provide sufficient reliability of rock pressure control in the known technical solution. The possibility of dynamic manifestations of rock pressure and collapse of roof rocks negatively affects occupational safety.

The technical task is to increase the reliability of managing rock pressure due to a more accurate formation of the arch of natural balance in the overlying rocks and to increase labor safety by reducing the likelihood of dynamic manifestations of rock pressure and mass collapses.

The problem is solved in that in the method of controlling rock pressure, including the sinking of preparatory rifling workings, working out the primary chambers of the trapezoidal section and filling them with a hardening mixture with the formation of artificial pillars, the formation of a massive ore pillar between artificial pillars and the redistribution of rock pressure to artificial pillars by partial mining reserves of the marginal parts of a massive ore pillar expanding upward chambers of artificial pillars, landing production in overlying roof rocks, drilling of blast holes from it within the natural balance of overlying roof rocks over a massive ore whole, complete unloading of a massive ore pillar by forced collapse of roof rocks between artificial pillars onto upwardly expanding chambers, creation of artificial pillars for collapsed rocks and mining reserves massive ore pillar with the support of overlying roof rocks with a set of natural equilibrium, based on artificial pillars and forms retaining slopes at the sides of artificial pillars during shipment of broken ore in accordance with the proposed technical solution, the mine workings pass along the axis of symmetry of the massive ore pillar in contact with the ore deposit, and blast holes from the mine workings are drilled radially so that the ends of these wells most accurately formed the size and surface of the contour of the specified arch of natural equilibrium in accordance with the calculated tensile strength of the array of overlying pores od.

Carrying out a landing mine along the axis of symmetry of a massive ore pillar in contact with the ore deposit allows it to be placed outside the zones of increased stress concentration created when redistributing rock pressure to artificial pillars by partially mining the reserves of a massive ore pillar. This reduces the likelihood of dynamic manifestations of rock pressure in the landing during the work on forced collapse. In addition, there is no need to perform two types of landing workings (in the well-known technical solution - drifts and spans), which further reduces the stress concentration around the landing workings and allows to reduce the total cost of landing workings and drilling blast holes by 10 ÷ 12%.

Drilling blast holes from the radial drilling hole and more accurate control of the length and angle of the blast holes allows you to most accurately form any size and surface contour of the arch of natural equilibrium in accordance with the calculated tensile strength of the array of overlying rocks.

The combined action of the distinguishing features described above allows us to achieve the solution of the technical problem posed - improving the reliability of rock pressure control by more accurately forming a set of natural equilibrium in the overlying rocks and improving labor safety by reducing the likelihood of dynamic manifestations of rock pressure and mass collapses.

It is advisable to partially develop the reserves of the marginal parts of the massive ore pillar by expanding upward chambers of adjacent artificial pillars in such a way that these chambers, which are at the same mining stages, form a step front of the treatment works.

This additionally reduces the stress concentration along the front of the sewage treatment plant, reducing the likelihood of dynamic manifestations of rock pressure and mass collapse, resulting in increased safety.

Thus, the combined action of the above features provides the most effective solution to the problem.

The essence of the technical solution is illustrated by the example of a method of controlling rock pressure during underground mining of a horizontal ore deposit and drawings, in which Fig. 1 shows a vertical section of the ore body orthogonal to the direction of advancement of the front of the treatment works (section AA in figure 2) at the time of drilling by the arch of natural equilibrium over the extreme massive ore whole; figure 2 is a plan of the release horizon (section BB in figure 1); figure 3 is the same section aa in figure 2 at the time of completion of the work on the arch of natural equilibrium over the extreme massive ore as a whole and conducting drilling and delivery workings in it; figure 4 is the same section aa in figure 2 at the time of full mining of the extreme massive ore pillar.

The proposed method is implemented as follows.

On ore deposits 1 (figure 1) are preparatory rifting 2 and work out the primary chamber 3 of a trapezoidal cross section (figure 2) at full capacity ore deposits 1 drilling and blasting method. After working off the primary chambers 3 of a trapezoidal cross section for the entire length z, they are filled with a hardening mixture with the formation of artificial pillars 4, between which a massive ore pillar 5 is formed, parallel to the front 6 of the treatment works. The redistribution of rock pressure on artificial pillars 4 is carried out by partial mining of reserves of the marginal parts of a massive ore pillar 5 by upward expanding chambers 7 of artificial pillars 4 (Fig. 1). To ensure the preservation of artificial pillars 4, it is preferable to drill wells 8 and blast them in layers (Fig. 2) with mechanical release and shipment of broken ore 9.

After the redistribution of the rock pressure on the artificial pillars 4, the mine 10 is drilled in the overlying rocks 11 along the axis of symmetry of the massive ore pillar 5 in contact with the ore deposit 1. From the mine 10, radially explosive wells 12 are drilled within the natural balance of the overlying rocks 11 above the massive whole ore 5. Blast holes 12 are drilled so that their ends most accurately form the dimensions and surface of the contour of the arch 13 of natural equilibrium in accordance with the calculated limit p the accuracy of the array of overlying rocks 11. For the formed span L of the arch 13 of natural equilibrium (Fig. 1) above the massive ore whole 5, the height h of the arch 13 of natural equilibrium is determined by the well-known formula:

h = L / 2f,

where f is the strength of the overlying rocks 11 on the scale of prof. M.M. Protodyakonova (f = R / 10);

R is the estimated resistance of the overlying rocks to 11 compression, MPa.

Blast holes 12 have different lengths. The minimum length l _min will be in vertical blast holes 12 (figure 1):

l _min = hh _in ,

where h _in - the height of the landing workings 10.

The maximum length l _max will be in blast holes 12 above expanding upward chambers 7:

l _max = (0.25L ² -W ² ) ^0.5 -0.5b _in ,

where W is the length of the line of least resistance;

b _in - the width of the landing workings 10.

The angle α between the blast holes 12, respectively, is determined from the ratio α = arctg (W / h).

Then produce a forced collapse of the overlying rocks 11 of the roof between the artificial pillars 4 on the chambers 7 expanding upwards, as a result of which a complete unloading of the massive ore pillar 5 is achieved. The collapsed rocks 14 fill the chambers 7 expanding upwards (Fig. 3), creating a backwater for artificial pillars 4. The reserves of the massive ore pillar 5 are worked out under collapsed rocks 14, after which retaining slopes 16 (Fig. 4) and sub neighing of the overlying rocks 11 of the roof is carried out by a vault 13 of natural equilibrium, based on artificial pillars 4 and retaining slopes formed at their lateral surfaces during shipment of the beaten ore 16. For a sufficiently powerful ore deposit 1, a massive ore pillar 5 is worked out with division into sub-floors, by drilling wells 8 and their blasting from drilling and delivery workings 17. After the solid ore pillar 5 has been completely worked out over the entire length z, the front 6 of the treatment works is shifted to the right and the cycle of operations for managing rock pressure at odzemnoy development ore deposit 1 is repeated.

It is advisable to break off the ore deposit 1 in adjacent massive ore pillars 5 to conduct in such a way (figure 2) so that expanding up the chamber 7, which are at the same stages of mining, form a step front 6 treatment works. This reduces the stress concentration along this front 6 treatment works on artificial pillars 4 by 25 ÷ 30%, resulting in additionally increased safety.

Claims (2)

1. The method of controlling rock pressure, including the sinking of the pre-cut mines, the development of the primary chambers of the trapezoidal cross-section and filling them with a hardening mixture with the formation of artificial pillars, the formation of a massive ore pillar between artificial pillars and the redistribution of rock pressure to artificial pillars by partial mining of reserves of the edge parts of massive ore pillar expanding upward chambers in artificial pillars, carrying out landing workings in the overlying rocks of the roof drilling of blast holes from it within the arch of natural equilibrium of overlying roofing rocks over a massive ore whole, complete unloading of a massive ore pillar by forced collapse of roofing rocks between artificial pillars onto chambers expanding upward, creating a backwater for artificial pillars with collapsed rocks and mining of massive ore pillars with maintaining overlying roof rocks with a set of natural equilibrium, based on artificial pillars and artificially formed at the lateral surfaces pillars in the process of shipment of the beaten ore retaining slopes, characterized in that the landing hole pass along the axis of symmetry of the massive ore pillar in contact with the ore deposit, and blast holes from the landing hole are drilled radially so that the ends of these wells most accurately form the dimensions and surface the contour of the specified arch of natural equilibrium in accordance with the calculated tensile strength of the array of overlying rocks. 2. The method according to claim 1, characterized in that the partial mining of the marginal parts of the massive ore pillar by expanding upward chambers of adjacent artificial pillars is carried out in such a way that these chambers, which are at the same mining stages, form a step front of the treatment works.

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