RU2248448C1 - Method for extraction of steep-falling deposits of weak ores - Google Patents

Abstract

FIELD: mining industry.

SUBSTANCE: method includes driving ventilation-backfill and drilling-loading gains, extraction of mineral resource by cross-directed chambers of rhombic or ellipsoidal shape, with displacement of adjacent levels chambers for half their width, with extraction of ore by wells explosion and backfill of extracted space. Directly above upper level protective ceiling is constructed with slant 5-6° towards hanging side of deposit. Width, height of chambers an height of upper level chambers, slanting angle of side walls of chambers is determined from mathematical expressions, on basis of stable calculated span of protective ceiling, width of drilling-loading gain and angle of inner friction of ore massif. After construction of protective ceiling ore in chamber is extracted by mines by exploding wells in compressed environment, while next mine is extracted after backfill of previous one. In unstable rocks, prone to cave-in, face of cleaning chambers is slanted at angle, appropriate to angle of natural slant of ore massif. In ores with rock layers cleaning chambers face is slanted at angle, appropriate for angle of falling of ore deposit.

EFFECT: higher safety, higher efficiency.

3 cl, 4 dwg

Description

The invention relates to the mining industry and can be used to develop powerful, tens and hundreds of meters, steeply falling deposits of weak ores in conditions where it is necessary to prevent the collapse or sediment of the ore and rocks covering the mined space (under the bottoms of pits, ponds, the thickness of the watered Quaternary deposits) .

Known methods for the development of ore bodies of high power in layers in ascending and descending order with the laying of the worked out space. Known methods for the development of ores under artificial roofing cameras with the laying of the worked out space [Kadolba N.N., Subbotin V.M., Nelaev V.A., Lyabakh A.I., Zhurin S.N., Zhidkov A.A. Technical solutions for the construction of the mine. Mining Journal No. 1-2, 1996, pp. 72-76].

The drawback drawback in the ascending order with respect to weak ores is the need to fasten the roof of the treatment chambers in the worked out layer, as well as the risk of large outfalls from the roof of the chambers, followed by sedimentation of the covering ores and rocks. The drawback of the layered development system in the descending order is that due to the inevitable shrinkage of the filling material and possible under-deposit when filling the chambers with the filling, the deposit of the filling mass and covering ores and rocks are disturbed with a violation of their waterproofing properties.

There is a method of developing powerful ore bodies by cameras of a polygonal shape in a descending order with the tab of the worked out space [SU, copyright certificate 1638302, cl. E 21 C 41/16, 1990] with the displacement of the chambers of the underlying floor by half the width of the chambers. The disadvantage of this method, in relation to weak ores, is the presence of vertical exposure in the ore mass in the walls or one wall of the chamber. Spontaneous, uncontrolled collapse of the walls of the chamber will lead to complications in the development of an adjacent chamber and can cause upsetting of filling material in the roof of the working chamber.

Known chamber system for the development of minerals using chambers of elliptical shape and concrete laying, the displacement of the chambers of adjacent floors by half their width [SU, copyright certificate 134242, 1960]. The lack of a development system for A.S. 134242 is that the geometric parameters of the chambers are not related to the stability of the outcrops of the ore mass and overburden.

The prototype adopted a version of the development system with elliptical cameras, considered in [Myasnikov K.V., Rudenko V.V. The use of hardening bookmarks in the development of ore deposits. - M .: Nedra, 1964, p.20-21]. In relation to the conditions under consideration, the disadvantage of the known system is that the geometric parameters (height and width) of the elliptical chambers are not linked to the stability of the ore mass. Accordingly, in weak, friable ores, the system does not exclude the possibility of collapse of ore outcrops in the lower half of the chambers and, as a result, deformations of the filling mass in its upper half, which can cause precipitation of the protective cover. In addition, the drilling unit in the ore mass must be fixed. When breaking ore in a run, the lining elements will complicate the shipment of ore.

The technical result of the invention is to increase the safety of mining powerful steeply falling deposits of weak ores lying under the bottoms of quarries or under the thickness of flooded Quaternary sediments, the underworking of which is associated with the risk of groundwater breaking into the working space of the mine.

The technical result is achieved by the fact that in the method for developing powerful steeply falling deposits of weak ores in a descending order, including the excavation of ventilation filling and boring loading orts, the extraction of minerals oriented crosswise extending by cameras of a rhombic or ellipsoidal shape, with the displacement of the chambers of adjacent floors to half their width, with According to the invention, a protective ceiling with a slope of 5-7 ° in s is constructed according to the invention directly above the upper floor by blasting a hole and laying a mined-out space. Oron hanging wall deposits, and the width B, height h, the height of the top floor of cameras ₁ h, the inclination angle θ of the side wall chambers is determined from the expression:

where B is the width of the chamber, m;

h is the height of the chamber, m;

h ₁ - chamber height of the upper floor, m;

L _ycm. - stable design span of the protective floor, m;

in - the width of the delivery unit, m;

θ, ρ - respectively, the angles of inclination of the side walls of the chambers and internal friction of the ore mass, deg,

after which the ore in the chamber is developed by drilling blast holes in a clamped medium, and the next drill is worked out after laying the previous drill.

In unstable, prone to collapse ores slaughtering treatment chambers give a slope corresponding to the angle of repose of the ore mass.

In ores with rock layers, the slope of the treatment chambers is given a slope corresponding to the angle of incidence of the ore deposit.

The invention is illustrated by drawings, in which Fig. 1 shows a diagram of the preparation and development of a block by a floor-and-chamber system for developing loose ores in a descending order under a protective overlap, a vertical cross-section across the strike, Fig. 2 is a plan of the preparatory and rifled workings of the upper floor; figure 3 is a diagram of the mining chambers of the upper floor; figure 4 - the order of the notches and bookmarks of the chambers during mining block, a vertical section along the strike.

In figures 1-4, the numbers denote:

1 - rocks of the lying side of the ore body;

2 - ore;

3 - rocks hanging side;

4 - protective overlap;

5 - recoil drift;

6 - ore passing;

7 - unloading chamber;

8 - field drift for driving workings of a protective floor;

9 - ventilating and uprising;

10 - field ventilation and stowage drift of the 1st floor;

11 - ventilation and filling unit of the 1st floor;

12 - field delivery drift of the 1st floor;

13 - drill loading unit of the 1st floor;

14 - ventilation and stowage drifts of the 2nd - 4th floors;

15 - delivery drifts of the 2nd, 3rd, 4th floor;

16 - drill loading unit of the 2nd floor;

17 - drill loading unit of the 3rd floor;

18 - drill loading unit of the 4th floor;

19 - ventilation and stowage drifts of the hanging side;

20 - ventilation and filling unit of the 2nd floor;

21 - ventilation and filling unit of the 3rd floor;

22 - transport biases;

23 - entry with broken ore;

24 - bookmark filled in bookmark.

25-30 - cameras on the 3rd floor at different stages of their development and bookmarks.

The panel preparation diagram is shown in FIG. Ore is discharged to the haulage drift 5 from the discharge chamber 7 through the ore pass 6. The ore is transported to the chamber 7 via a field delivery drift 12 from a loading unit 13. Ventilation and filling units 11 pass from a field ventilation and filling drift 10. Delivery levels of the floors are connected by transport slopes 22 To feed the bookmarks to the 2nd, 3rd and other lower floors, ventilation and filling drifts 19 in the hanging side of the 3 ore deposits and ventilation and filling gates 20, 21 are placed in the ore at the junction of the filling mats ssiv neighboring cameras. The mining of the chambers is carried out in the direction from the rocks of the hanging side 3 to the lying side 1 by sinking 23 with a length of 4-10 m. Each sinking 23, 24 is laid down after the shipment of ore.

A protective floor 4 is built directly above the upper floor from the lying side with a slope of α = 5-7 ° to the lying side, to ensure that the bookmark under the protective floor is flowing and to prevent under-laying of the upper floor chambers, which can cause deformation of the floor. To prepare the upper floor for the recess directly under the protective ceiling 4 pass ventilation and filling orths 11 and boring loading orts 13 at the level of the first delivery horizon (figure 2). The distance between the axes of the unit vectors along the strike of the ore body corresponds to the width of chambers B, which does not exceed the calculated value of the stable span of the protective floor L _ycm . In turn, a stable span of the ceiling depends on the load on the ceiling, its design and material.

The height of the upper floor chambers located directly under the protective floor is approximately equal to their width and less than the calculated stable span of the artificial floor.

The height of the chambers of the 2nd and other lower floors is equal to twice the height of the floor.

Figure 3 in the center shows the primary chamber of the upper floor, laid with concrete. The secondary chamber (on the right) is shown at the time of ore shipment after breaking the undercut layer and drilling wells in the upper layer. The chamber of the third stage (left) is prepared for the explosion of wells in the hook.

The chambers of the 2nd floor (Fig. 4) are prepared by sinking ventilation and filling slots 20 and loading shafts 16 of the second delivery horizon. Ventilation and filling gates 20 are passed through the ore, cut to the tab at the junction of the filling arrays of adjacent chambers of the 1st floor. During the preparation of the 3rd floor, ventilation and filling horns 21 pass through the ore under the laying of the 1st floor chambers, boring loading horts 17 pass and are supported in the ore mass.

The cameras work out short, 4-10 m long, calls, in a clamped environment. The cast is developed in two layers. The bottom layer is undercut. Wells of the undercut layer are drilled from the lower boring loading unit 17, wells of the upper layer are drilled from the ventilation-filling unit 21.

The order of technological processes in the chambers is illustrated by working out the 3rd floor, Fig. 4. Chamber 25 - spent, filled with a bookmark; 26 - chamber with broken ore; 27 - a chamber prepared for drilling; 28 - camera before bookmark; 29 - camera before breaking the undercut layer; 30 - camera after shipment of ore from the undercut layer. At the same time as advancing, there are boring loaders on the 18th floor.

The sequence of mining chambers should exclude the underworking of the stowage array of overlying floors. This condition is ensured if the chambers adjacent to the working chamber are filled with filling material that has gained standard strength, or have not yet been developed (ore pillar).

The proposed development method virtually eliminates the collapse of a loose ore mass before laying the chamber, since ore outcrops in the sides of the chambers are limited by the entry length and are formed at an angle of repose. At the ends of the chamber from the side of the lying side of the collapse are possible. To prevent them in unstable ores, the plane of the end face is given an inclination at an angle β to the horizon, Fig. 1. The minimum value of the angle β corresponds to the angle of repose. In this case, the bookmark will hang over the ore, so the strength of the bookmark should be increased.

By changing the angle of inclination of the plane of the ore face of the chamber also solve the problem of selective extraction of ores of various qualitative composition. In such cases, the angle of inclination of the ore face should be the same as the angle of inclination of the contact surface between the ore varieties. Then, when meeting the working face of substandard ore or rock layers, they can be left in the stowing massif.

It is advisable to fasten the load-carrying orts in a weak ore mass with a frame trapezoidal support with racks consisting of 2 elements connected by a wedge lock. The lining is easily removed, which must be performed on a unit of Orth with a length equal to the length of the run from the end of the chamber. This operation is performed before drilling the holes in the hook, so that in case of ore outbursts during disassembly of the lining, the layout of blast holes can be adjusted, which in this case is drilled from the fixed section of the unit metal, inclined to its axis. Before laying the chamber, the drill loading unit is closed with a jumper.

Distinctive features of the invention can improve the efficiency and safety of the development of powerful steep-dipping deposits stacked with loose ores, and provide the following advantages over other development systems under protective overlap:

- reliable maintenance of the ore-rock ceiling above the protective floor due to the constant and quality-assured contact of the filling arrays of the chambers of adjacent sub-floors along their lateral faces;

- the exception of the collapse of ore from the sides of the chambers;

- minimum amount of preparatory work; at the same time, half of the preparatory workings (ventilation-stowing horns) are passed and supported under the stowage array and do not require fastening;

- the possibility of selective excavation of an ore body of complex structure;

- minimization of dilution and loss of ore;

- safety of work due to the lack of people in the face.

Claims (3)

1. A method for developing powerful large-falling deposits of weak ores, including sinking of ventilation-filling and drilling-loading units, mining of minerals oriented crosswise with chambers of rhombic or ellipsoidal shape with a displacement of chambers of adjacent floors by half their width, with excavation of ore by blasting of holes and laying mined-out space, characterized in that immediately above the upper floor a protective ceiling is constructed with a slope of 5-7 ° towards the hanging side of the deposit, and the width B and height h ka measures, the height of the chambers of the upper floor h ₁ , the angle of inclination of the side walls of the chambers θ is determined from the expressions:

where B is the width of the chamber, m; h is the height of the chamber, m; h ₁ - chamber height of the upper floor, m; L _yct. - stable design span of the protective floor, m; in - the width of the drilling and loading unit, m; θ, ρ - respectively, the angles of inclination of the side walls of the chambers and internal friction of the ore mass, deg, after which the ore in the chamber is developed by drilling blast holes in a clamped medium, and the next drill is worked out after laying the previous drill. 2. The method according to claim 1, characterized in that in unstable, prone to collapse ores slaughtering treatment chambers give a slope corresponding to the angle of repose of the ore mass. 3. The method according to claim 1, characterized in that in ores with rock interlayers the slope of the treatment chambers is given a slope corresponding to the angle of incidence of the ore deposit.

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