SU1735585A1 - Open-pit mining method for steep and inclined deposits - Google Patents

Abstract

The invention relates to the mining industry and can be used in the development of steeply dipping and oblique deposits of high power. The purpose of the invention is to reduce the cost of development of overburden with increasing depth of development, increasing the rhythm of production, reducing losses and increasing the volume of discovered mineral reserves at the opening of deposits represented by complete deposits. Initially, mining operations are carried out in the opening block in the direction of the lying or hanging side of the deposit with their simultaneous deepening and internal dumping. Then develop mining work on the end board to the border of the career floor. Mining is done in horizontal or inclined layers with a gradual decrease in mining. The overburden rocks are placed in a temporary technological space and at the bottom of a pit formed at an angle less than the angle of repose of the rocks. The depth of the career lead in the opening block. 3 zp. Ly, 8 ill. SO with

Description

The invention relates to the mining industry and can be used in the extraction of minerals in quarries, working steeply dipping and inclined deposits, represented by a suite of high power.

There is a method of opencast development of steeply dipping deposits, in which the deposit of an advanced quarry is opened to the depth of the first stage with the placement of overburden rocks in the external dump, after which the minerals are dredged and the pit walls are separated with the overburden in the developed space first.

career, and after its filling and moving the front of mining operations, in the newly formed developed space. Dump dump lead rusami. After the approach of the mining front to the boundaries of the quarry floor, the pit of the next stage is deepened. If this also requires the separation of the bead, which is represented by the internal waste dumped by the Rus, the overburden rocks of this blade in the outlines are moved to the external dump. Next, mining works in the opposite direction with the movement of the overburden rocks of the inner dump of the first-stage open pit to the open pit of the next stage (line). VnutVI

GJ SL SL 00 SL

The dumps also move overburden rocks of this line.

The main disadvantage of this method is the large amount of overburden movement. So, when mining a quarry in two stages, the first stage overburden rocks must be moved twice. With three bursts, the overburden of the first batch is moved three times, and the second batch - twice. All this ultimately reduces the efficiency of mining.

The closest to the proposed method is the opencast development of steeply dipping and inclined deposits, including opening the deposit on one of its flanks at the boundary of the quarry floor with the placement of overburden in the outer dump, excavation of minerals and overburden in the face board of the open pit. the bot along the strike of the field to the opposite boundary of the quarry floor, the placement of overburden rocks on the bottom of the developed space following the movement of the working side to arcs with the creation of a technological excavated space at a specified border, a dredging of a quarry with movement of overburden rocks and excavation of a mineral to the maximum depth of open pit mining.

The disadvantage of this method is also the impossibility of reaching open depths of considerable depths due to the need for high costs for the development and movement of overburden. When excavating split trenches across the deposits and dredging of rocks during the period of opening the field (first stage of mining), the excavation of minerals alternates with the excavation of overburden, which does not ensure the creation of a standard amount of discovered mineral reserves, causes arrhythmia in mineral mining (especially when overburden seams), increases mineral losses in case of sloping deposits and in the case of mining of steep and sloping deposits from the side of their bed time.

The aim of the invention is to reduce the cost of development of overburden while increasing the depth of development, increasing the rhythm of production, reducing losses and increasing the volume of overburden reserves of minerals at the opening of deposits represented by a suite of deposits.

The goal is achieved by the fact that in a known method of developing steeply dipping and inclined fields, including the opening of a deposit on one of its flanks within the boundaries of the quarry floor with the placement of overburden rocks in the outer heap, the development of the mining front along the strike to the opposite flank of the deposit with an end face of the pit with a notch minerals and the placement of overburden at the bottom of the excavated space, revealing the production is carried out on the side of the hanging or lying side of the deposit, first Primer recess leading towards recumbent or hanging side which deposits during chiseling unit while its recess and the formation of the end edge of the pit with working areas.

The bottom of the open space of the opening block is formed at an angle to the horizon, smaller than the angle of repose of overburden rocks, and an internal dump of the said rocks is placed on it, and when approaching the boundary of the quarry floor from the side of the lying or hanging side of the deposit, they form a temporary technological space that is filled overburden rocks from the subsequent development of the front of mining operations on the front side, and the advancement of the front of mining operations is carried out with their simultaneous deepening and the formation of the bottom of the worked out a nd at an angle to the horizontal, the smaller the angle of repose placed thereon overburden and further uglubki career is produced in t necropsied and overburden block is moved in otuglubki formed technological goaf.

In addition, the excavation in the opening unit and the advancement of the mining front are carried out by horizontal layers with step-shaped as well as inclined layers and a combination of horizontal and inclined layers forming the bottom of the worked-out spaces.

FIG. Figure 1 shows the open pit at the time of completion of the opening block, plan; in fig. 2 - open pit at the time of complete filling of the overburden rocks of the temporary technological space of the opening unit, plan; in fig. 3 - open pit after a dredging of a open pit in the opening unit, plan; in fig. 4 shows section A-A in FIG. one; in fig. 5 is a section BB in FIG. 2; in fig. 6 is a sectional view BB in FIG. 3; in fig. 7 and 8 are the pit projections on the vertical plane along the strike of the deposits when working with inclined layers with simultaneous insertion into three layers.

The method is carried out as follows.

Initially, on one of the flanks of a steeply dipping or sloping field, represented by deposits of high power and having significant dimensions both along the strike and across the strike of the deposits, is opened, for example, by a split trench 2, passed along the strike of the deposits 1 from the side of which or the recumbent sides of deposits. The overburden rocks from the penetration of the split trench 2 are stored in the outer edge of the dump 3. Then move the board

4 trenches in the direction respectively to the lying or hanging side of the deposits in the hiding block 5 along the entire length of the overburden with simultaneous deepening of the mining operations and formation of the bottom of the excavated space 6 at an angle less than the angle of natural slope of the overburden located on it. Overburden rocks 7 are laid on the bottom 6 so formed. Transportation of overburden rocks is carried out along the transport berms of the front side of the non-working pit bead 8. The inner dump layers 9 are poured to form a free space 10, where transport communications are placed to transport the mineral. With insufficient receiving capacity of the developed space of the opening unit

5 form additional Russes of the inner blade 11 and the outer blade 3. On the recessed end face 12, in the process of dredging mining, working sites (not shown) are created. At the approach of mining to the border of the career floor 13 form a temporary technological space 14.

Then, after the opening block 5 is placed in the final position, the excavation of the mineral and overburden rocks is carried by end face 12 along the direction of the deposits to the boundary of the quarry floor 15 with simultaneous deepening of the mining operations. In this case, the bottom of the pit 16 is formed at an angle to the horizon smaller than the angle of repose of the overburden placed on it.

The overburden, developed during the development of mining operations on the end face 12, is moved along the transport berms of the non-working sides 8 and 17 into the temporary technological space 14. With the subsequent advance of the end edge 12 to the boundary of the quarry floor 15, the overburden rocks are moved to the internal dump 18 along the transport berms, located on non-working boards 19 and 20. On non-working boards, congresses are also organized to deliver minerals to the surface of the quarry. With the approach of mining to

The boundary of the quarry floor 15 forms the technological space developed (not shown), and the face flange 12 is placed in the end position 21.

In the case of reaching the maximum depth of the quarry before setting the end flange 12 to the final position 21, no further excavation is performed and mining works are developed with the formation of the bottom of the worked-out space in the form of a single step.

5 It is possible to develop the deposit both in the opening unit 5 and the main production field in horizontal layers. In this case, for dredging of mining, split trenches are made on each ledge with subsequent movement of the ledge in the direction of development. Each successive lower trench is passed with an offset in plan with respect to the previous one (on the upper ledge) by a distance ensuring the creation of the pit bottom with a general angle of inclination not exceeding the angle of natural slope of the overburden located on it. Such

0 offset allows forming the bottom of the opening unit 5 and the bottom of the worked-out space on the main operating field with step steps.

It is also possible to work out the opening block and move the mining front on the main production field by inclined layers with simultaneous insertion into one or several layers 22 or a combination of horizontal and inclined

0 layers. The number of boxes 23 depends on the specified production capacity of the open-pit mine.

In this order of mining, significant reserves of mineral resources remain under the bottom of the open pit — reserves 24 under the opening block and reserves 25 below the main production floor. Therefore, after setting the face side 12 to the final position

0 21 on the opening block 5 and on the main production field, where the height of the internal dump is relatively small, previously stored overburden rocks are transferred to the technological opening 5 a secret space on the final contour and begin the excavation works on the block open with the movement of the overburden to the specified technological area and transportation of minerals at congresses established on the boards to the surface. At the same time, mining operations are developed to the maximum depth of open pit mining.

At the opening of the field, an external dump of 3 overburden is located inside the boundaries of the quarry floor in the instrument area between the opening block 5 and the boundary of the quarry floor. When dredging mining in the opening block 5, this blade is involved in the development, as it falls into the contours of the quarry. The overburden rocks of this dump are moved to the technological space developed on the final contour.

In the process of excavation of rocks at the bottom of the excavated space and on the sides of the quarry, underground mines 26 and 27, constructed by the open method, are used for the subsequent underground mining of podcaryne reserves 24 and 25 of the mineral. Their construction is carried out in stages, which provides for their permanent build-up and backfilling with internal dumps in the process of advancing the worker and the waste front of mining operations. Underground workings are located in trenches specially passed in the rock mass or directly in the body of the internal dump. The mining of under-pit reserves is carried out in conjunction with open mining or after it has been completed.

The use of the proposed method allows, compared with the known method, to reduce the costs for the development of overburden by reducing the amount of work on the re-development of overburden laid in the internal dump, and consequently, the final depth of open pit mining increases. The rhythm of mining increases due to the fact that there are no mixed faces during the period of discovery, the mineral and overburden rocks are being developed separately for independent mining. Losses are reduced due to the fact that the mining of deposits in the opening block leads along strike from the side of the deposits. The development of deposits along strike makes it possible to increase the volume of discovered mineral reserves.

Claims (4)

Claim 1. Inventory development of steeply dipping and inclined fields, including the opening of a deposit on one of its flanks within the boundaries of the quarry floor with the placement of overburden in external dump, the development of the mining front along the strike to the opposite flank of the deposit with an end edge of a quarry with a dredging of the mineral and placing overburden at the bottom of the open space, characterized in that, in order to reduce development costs of overburden while increasing the depth of development, increasing the rhythm of production, reducing losses and increasing the volume of discovered mineral resources at the opening of deposits represented by the retreated deposits, revealing passes from the side of the hanging or lying side of the deposit, initially dredging is carried out in the direction towards the lying or hanging side of the deposit in the opening unit with its simultaneous deepening and shaping pit sides with working platforms, the bottom of the open space of the opening block is formed at an angle to the horizon, less than the angle of repose of the overburden, and placed on it The internal dump of the said rocks and when approaching the boundary of the quarry floor from the side of the lying or hanging side of the deposit form a temporary technological space that is filled with overburden rocks from the subsequent development of the mining front on the end board, while moving the mining front with their simultaneous deepening and the formation of the bottom of the worked-out space is carried out at an angle to the horizon, less than the angle of repose of the overburden deposited on it, and further excavation of the quarry d t in block necropsied and overburden from dredging move to the formed technological developed space. 2. A method according to claim 1, characterized in that a recess in the opening unit and The advancement of the mining front is carried out by horizontal layers with stepwise formation of the bottom of the worked out spaces. 3. The method according to claim 1, characterized in that the recess in the opening unit and The advance of the mining front is carried out by inclined layers. 4. A method according to claim 1, characterized in that the recess in the opening unit and Moving up the mining front is a combination of horizontal and inclined layers. g -I, IIIIIIII tf A- + S to V / L i  I W4 L II / And in -r. J J -, t Izhi ts 4. R 2d  .;.:; /:; . . : .. //: .l; - ;;: - ;;; -: ;;; ::; .-:;: V -: v: -v: v -: R 27: with :: and g n.i l a ъ one to LC FIG. Have Tb Fig.Ј Fig.Z I / J I "five I o you U) P