RU2761226C1 - Method for the development of powerful gentle and inclined rock burst hazardous ore deposits - Google Patents

Abstract

FIELD: mining.

SUBSTANCE: invention relates to mining, namely to the underground development of gentle and inclined deposits of minerals, and can be used for the development of powerful rockburst hazardous and structurally disturbed sections of the mountain range. The development method includes the creation of an artificial roof in the form of a bearing vault by driving parallel different-height chambers of the first and second stages in contact with the host rocks and filling the worked-out space with hardening mixtures. Excavation of minerals under the created artificial roof with chambers of the first and second stages with backfilling of the worked-out space with hardening mixtures. The filling array is reinforced with anchors installed along the normal to the soil of the chambers. The thickness of the roof of the bearing vault, which is a layered split beam, is determined according to the principle of calculating a monolithic vaulted structure with a given load from the pressure of the overlying layers of the fill and the dead weight of the bearing vault. The required strength of the bearing vault, as a formed hinge system, is provided by a given condition.

EFFECT: improving technical and economic indicators, improving work safety, expanding the scope of the chamber development system, increasing the volume of the main chamber reserves and reducing the specific volume of mining and preparatory work.

1 cl, 2 dwg

Description

The invention relates to mining, namely to the underground development of gentle and inclined deposits of minerals and can be used for the development of powerful rockburst hazardous and structurally disturbed sections of the mountain range.

A known method for the development of gentle and inclined rockburst ore deposits called: chamber development system using an artificial roof. The development system provides for the formation of an artificial roof by driving parallel runs of the first and second stages at the contact with the host rocks at the level of the deposit roof. The developed space of the ends is laid with a hardening mixture. After the set with the hardening mixture of the standard strength, the minerals are taken out under the artificial roof with the chambers of the first and second stages. The development of cameras of the second stage is associated with the possibility, as practice has shown, of rock bursts. This was a significant disadvantage of this version of the chamber recess. (Drobot B.P. The current state of technology for underground mining of bauxite deposits // Izvestiya vuzov. Mining magazine. 1993. No. 10. Pp. 100-101).

There is also known a method for the development of ore deposits, including driving in the ore at the contact with the enclosing rocks of parallel runs of the first stage and between them driving of runs of the second stage, the formation of an artificial roof by filling the worked-out space of the runways, and the excavation of a mineral under the artificial roof is carried out by chambers of the first and second stages, coaxial to the run-in of the first stage, with the formation of the lateral contours of the goaf along the axis of the run-in of the second stage. (AS No. 1346793. Method for the development of ore deposits. Authors: Drobot BP, Berkovich V.Kh., Dik Yu.A., Pilenkov Yu.Yu., Bakinovsky II, Nelaev V.A. , Rempel PA, and Gorev ES - Application No. 4067430 dated 05/11/86, published 10/23/87. Bull. No. 39).

The disadvantage of this method is the low efficiency and safety of field development in conditions of impact occurrences in unstable host rocks of the hanging side of the ore body.

The objective of the claimed method is to increase the efficiency and safety of mining operations when creating an artificial roof and excavating chamber reserves under it due to:

- giving the artificial roof greater stability (strength) due to the formation of the supporting layer of the roof in the form of a monolithic vaulted structure and reinforcement of the filling array of the roof with anchors;

- a decrease in the level of acting stresses in the ore body due to the advanced mining of the hanging side;

- a decrease in the volume of mining and preparatory work per unit of production due to a significant increase in the main chamber reserves, mined under an artificial roof;

- elimination of the cost of fixing the roof of the chambers mined under an artificial roof, and a decrease in the rate of ore dilution with stowing material during stope excavation;

- leaving on the soil of the workings, traversed at the contact with the host rocks at the level of the deposit roof, a layer of chipped ore to mitigate the destructive impact of the explosion energy during borehole blasting of the main chamber ore reserves.

This task is ensured by the fact that in the method of developing powerful flat and inclined rockburst-hazardous ore deposits with unstable host rocks, including the creation of an artificial roof in the form of a bearing vault by driving parallel different-height chambers of the first and second stages at the contact with the host rocks and filling the worked-out space of the chambers with hardening mixtures, excavation of the created mineral under artificial roofing with chambers of the first stage with filling the worked-out space with hardening mixtures, and chambers of the second stage with filling the worked-out space with hardening mixtures, while an increase in the strength of the artificial roof is achieved by reinforcing the filling array with anchors installed normal to the soil of the chambers, the thickness of the roof of the bearing vault, which is a layered split beam, is determined according to the principle of calculating a monolithic vaulted structure with a given load from the pressure of the overlying layers of the fill and the dead weight of the bearing vault, and the required strength the bearing vault, as a formed hinge system, is provided under the condition:

where k is a coefficient characterizing the degree of stress concentration arising in the bearing vault of an artificial roof;

ξ - coefficient taking into account the mechanical properties of the bookmark;

k _p - surcharge coefficient , depending on the ratio of the total thickness of the overlying layers of the bookmark to the thickness of the roof of the bearing layer of the artificial roof (determined according to the graph of Fig. 2);

γ _n - volumetric weight of the bookmark, t / m ³ ;

l is the span of the chamber worked out under an artificial roof, m;

h _n - the thickness of the arch of the bearing layer of the artificial roof, m;

b is the width of the roof of the bearing layer, m;

σ _comp. - the strength of the laying of the bearing vault of the artificial roof, MPa;

σ _comp.n - standard strength of the insert, MPa.

The essence of the method is illustrated by drawings, where Fig. 1 shows the excavation of the main chamber ore reserves under the vault of an artificial roof; in fig. 2 - a graph of the dependence of the load factor is presentedk _P on the ratio of the total thickness of the overlying layers of the fill to the thickness of the roof of the bearing layer of the artificial roof∑ h _i / h _n , where curve 10 characterizes the surcharge corresponding to the gravity of the maximum number of layers of the bookmark; curves 11, 12 and 13 characterize the surcharge corresponding to the gravity of the overlying layers of the fill, equal to 0.25, 0.5 and 1 of tgβ respectively (whereβ - the angle between the normal to the centerline of the roof of the bearing layer in the section under consideration and the vertical axis).

The strength of the artificial roof, formed by the backfill, is significantly increased by giving it a shape close to the vault. The formation of the vault occurs, in turn, as a result of the development of the chambers of the first and second stages of different heights, which gives the artificial roof a ledge-like appearance, approaching in shape to the shape of the collapse vault. This makes it possible to exclude from the treatment cycle the fastening of the roof of the chambers mined under the artificial roof and to reduce to a minimum the dilution of the ore with the filling material.

A negative point in the technology of creating an artificial roof is that it turns out to be layered. Since the filling of a large volume of voids without technological breaks is practically impossible, the layers formed between the intervals when the filling mixture is not supplied to the chambers turn out to be unbound and peel off during collapse. To prevent the weakening of the artificial roof due to its layering (the thinner the layers and the more of them, the less stable the roof), it needs additional strengthening, which is possible through the use of anchor support or the installation of metal reinforcement.

Anchors 4 are installed in the artificial roof 1 before the start of its construction, i.e. before the start of feeding the bookmark into the upper undercutting layer. For this, short boreholes with a depth of 10-15 cm are drilled, metal anchors with a length of 1.5-2.0 m are installed in them, at the other end of which metal washers with a size of 15x15 cm are fixed. So that during the feeding of the bookmarks, the rods remain in an upright position in the upper part they are tied with a wire. After the filling mass has hardened, the anchors are already installed in it, and the attachment of metal washers to them prevents them from "sliding".

In some cases, when additional measures are required, metal reinforcement is mounted on the soil of the spent layer or, along with the installation of rods of the usual length of 1.8 m, rods up to 3-4 m long are installed.They are located along the axis of the chamber at a distance of 3-5 m from one another ...

Leaving on the soil the primary and secondary chambers-entry of the upper undercutting layer of the pile of chipped ore 5, which is taken during the development of the lower chambers, allows you to prevent the destruction of the artificial roof by blasting operations. Another solution to the issue of maintaining the stability of the artificial roof is a shortage of wells by 0.3-0.5 m before filling or breaking the upper part of the ore in the chamber under the artificial roof using the small-hole method.

Ore extraction under an artificial roof is carried out by primary and secondary chambers 2 and 3, which are positioned through one in such a way that their central axes coincide with the axes of the primary entry chambers traversed in the stage of creating an artificial roof, and their boundaries were on the axes of the secondary entry chambers ...

Backfilling of the goaf when creating an artificial roof is carried out with compositions that ensure the standard strength of the backfill array of at least 4 MPa. These strength characteristics correspond to the compositions of filling mixtures using metallurgical production as a binder cement and slags.

Calculations show that the thickness of an artificial roof with a vaulted bearing layer at the location of the first stage chambers during its creation can be no more than 3 meters, and the height of the second stage chambers is greater than the height of the first stage chambers by 1/2 of the total width of these cameras.

When carrying out pilot tests of the technology of chamber mining of reserves under an artificial roof in the conditions of mines of JSC "SUBR", the treatment block was prepared for the longwall excavation by a system of panel drifts 7. After the creation of an arched artificial roof, the main chamber reserves of the block were broken off by blowing fans of borehole charges 6, and the release, loading and delivery of the broken rock mass from chambers 8 were carried out by remote-controlled LHD trucks 9.

The development of a new technology and its implementation in mining ore bodies in rock-burst hazardous conditions and unstable host rocks made it possible to:

- to obtain high technical and economic indicators, in particular, to achieve the level of labor productivity of the downhole worker without taking into account the costs of stowing work of about 48 t / person - shift, to obtain indicators of ore losses of 2 - 3%, and dilution - 5%;

- significantly expand the scope of high-performance
chamber development system;

- to increase the safety of work by reducing the magnitude of the acting stresses in the ore body due to the advanced mining of the hanging side;

- to increase the volume of the main chamber reserves, to reduce the specific volume of mining and preparatory work and to increase the overall efficiency of mining.

Claims (11)

A method for the development of powerful gentle and inclined rock-burst hazardous ore deposits, including the creation of an artificial roof in the form of a bearing vault by driving parallel different-height chambers of the first and second stages at the contact with the host rocks and filling the worked-out space with hardening mixtures, excavating a mineral under the created artificial roofing chambers of the first and the second stage with the filling of the worked-out space with hardening mixtures, characterized in that the filling mass is reinforced with anchors installed normal to the soil of the chambers, the thickness of the roof of the bearing vault, which is a layered split beam, is determined according to the principle of calculating a monolithic vaulted structure with a given load from the pressure of the overlying layers of the fill and the dead weight of the bearing vault, and the necessary strength of the bearing vault, as a formed hinge system, is provided under the condition

where k is a coefficient characterizing the degree of stress concentration arising in the bearing vault of an artificial roof; ξ - coefficient taking into account the mechanical properties of the bookmark; k _p - surcharge coefficient , depending on the ratio of the total thickness of the overlying layers of the fill to the thickness of the roof of the bearing layer of the artificial roof; γ _n - volumetric weight of the bookmark, t / m ³ ; l is the span of the chamber worked out under an artificial roof, m; h _n - the thickness of the arch of the bearing layer of the artificial roof, m; b is the width of the arch of the bearing layer, m; _σcomp is the strength of the filling of the bearing vault of the artificial roof, MPa; σ _comp.n - standard strength of the insert, MPa.

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