RU2064582C1 - Method for openpit mining of minerals - Google Patents

Abstract

FIELD: mining. SUBSTANCE: method for openpit mining of minerals includes forming sections of interim idle side in working area of the open pit. The sections are alternate to operating horizons. Separation of upper interim idle side concurrently with its forming through bringing lower operating horizons into interim idle state. Filling protective banks to catch rolling stones at horizons through spacings along depth equal to the height of sections of interim idle side. Providing haulage berms in permanent or semi-stationary pit side at horizons used to place protective banks. A system of ramps from horizons of protective banks to lower operating horizons within interval along the depth equal to the height of interim idle side. EFFECT: higher efficiency. 2 dwg

Description

 The invention relates to the field of mining and may find application in the open development of mineral deposits.

 There is a method of open development of deposits with the allocation in the quarry of the stages of development. In this method, intermediate contours with an inclination angle greater than the inclination angle of the working side are distinguished inside the conical contour of the quarry. Mining operations on horizontal, reaching the contour of the quarry of the first stage, stop, forming a temporarily idle side.

When the temporarily non-working side on the contour of the first stage reaches the calculated height, it begins to spacing to sequentially move the ledges to the contour of the second stage quarry, where they also begin to form a temporarily non-working side, etc. [1]
Of the known methods of open-pit mining, the closest in technical essence to the proposed invention is a method with highlighting the stages of its development in a quarry.

The main technological feature of the prototype is the alternation in depth of the quarry of the sections of the temporary idle side with the working horizontals according to their spacing and the spacing of the upper horizons of the temporarily idle side simultaneously with its formation by bringing the temporarily idle position below the working horizons [2]
Indeed, when the temporarily idle side on the contour of the first stage reaches the calculated height, the separation of its upper horizons begins, but at the same time, the height of the temporarily idle side from the bottom continues due to the ongoing deepening of the quarry. Thus, the temporarily idle side section “slides” along the contour of the stage. Similarly, the areas of temporarily idle side formed on the contour of subsequent stages are worked out.

 The economic efficiency of the development method for the prototype is achieved by reducing the current stripping ratio by increasing the resulting angle of inclination of the working side of the quarry. Moreover, the efficiency increases with increasing angle of inclination of temporarily idle sides.

 The application of the prototype technology described above for the development of a rock mass is associated with the fact that the separation of the upper horizons of the temporarily idle side is inevitably accompanied by the release of rock mass during blasting. As a result, with a sufficiently steep angle of inclination of the temporarily idle side, its entire slope can be completely covered with blasted rock mass. This excludes the possibility of locating openings in areas of a temporarily idle side and does not provide conditions for safe mining operations when they are brought into a temporarily inoperative position below the working horizons. In practice, such negative phenomena are avoided by the fact that a temporarily idle side is formed with sufficiently wide berms, which make it possible to place an ejection of blasted rock mass on one or two horizons. But this leads to a flattening of the resulting angle of inclination of the working side of the quarry and, therefore, to a decrease in the efficiency of the technology under consideration according to the prototype.

 Another method that is used in practice to create conditions for safe mining is the filling of protective shafts to catch rockfall. However, this method is notable for the uncertainty of actions, since it is not known at what horizons to form barrier walls. In addition, in order to minimize the current stripping ratio, it is advisable to form sections of the temporarily idle side along the entire length of the open side of the quarry. In this case, the sections of the temporarily idle side are interfaced with a constant side. But in conditions of the impossibility of maintaining the openings in the working condition on the slope of the blasted rock mass temporarily idle, transport departure to the permanent side is carried out only from the working horizons by the separation of temporarily idle sides, the elevations of which are constantly decreasing. This requires the formation of a permanent berry on almost every horizon of the transport berms, which leads to a sharp decrease in the angle of inclination of the constant side of the quarry, to an increase in the average and current overburden ratios. Therefore, in practice, temporarily non-working sides are formed not along the entire length of the working side of the quarry, but only on its part, which makes it possible to lift the rock mass from the working horizons by spacing the pillars within the working area free from sections of the temporarily non-working side. But this in turn leads to an increase in the current stripping ratio, which reduces the effectiveness of the development method of the prototype.

 The aim of the present invention is to remedy these disadvantages and reduce the current stripping ratio when using the development method by increasing the resulting tilt angle of the working side of the quarry.

 This goal is achieved by dumping the barrage shafts for catching rockfall on the horizons of the temporarily idle side at depth intervals equal to the height of the sections of the temporarily idle side, by means of a transport berth in the permanent or semi-stationary side of the open pit of the open pit at the horizons of the location of the deflecting side walls and the formation of exit ramps in the working side of the open pit placement of barrier shafts to lower working horizons within the interval in depth equal to the height of the temporarily irregular section on board.

 Figure 1 shows a diagram of a quarry plan; figure 2 section of the career aa in figure 1.

 The numbers 1-18 indicate the marks of the horizons of the working board from top to bottom, the rectangles of the 19 exit system in the working board of the quarry. The dashed-dotted lines 20 show the position of the barrage shafts for trapping rockfall, the figure 21 transport berm in the permanent or semi-stationary side of the quarry at the horizons of the barrage shafts, in this case, on horizon 6 and horizon 12. The numbers 22 indicate the position of the openings in the permanent side, 23 sections of the permanent or semi-stationary side of the quarry, 24 ore body. The dashed line in figure 2 shows the position of the working side at the time of filling the barrier shaft in a new position on horizon 6, and the triangles 25 containment shafts corresponding to this position of mining. Figure 1 solid horizontal lines shows the position of the slopes of the ledges on the working and temporarily non-working horizons.

 In the position of mining operations shown in FIG. 1, work platforms are formed at horizons 3, 4, 10, 11, 16 and 17. They are the working horizons for the separation of sections of the temporarily idle side. On the presented plan of the quarry, three sections of the temporarily idle side are formed: the upper section is formed from ledges at horizons 1, 2, 3, the middle section from the ledges at horizons 5, 6, 7, 8, 9, 10 and the lower from the ledges at horizons 12, 13 , 14, 15, and 16.

 The estimated height of the sections of the temporarily idle side is in this case the total height of the six ledges. The lower section of the temporarily idle side has a variable height: from six steps, it continuously decreases due to the difference in the spacing of the pillar and the build-up from below.

 The height of the barrier shaft and its location relative to the lower edge of the ledge on the horizon of the shaft is determined by calculation according to the known method. With a sufficiently high height of the section of a temporarily idle side, for example, as in this case, with a height of ledges of 15 m, it will be 90 m, the distance between the barrier shaft and the lower edge of the ledge reaches 20-25 m.

 In the mining plan shown in FIG. 1, three exit systems are formed on the working board of the quarry. The first system opens the working horizons 3 and 4 from the day surface, the second system opens the working horizons 10 and 11 from the horizon 6 of the placement of the barrier shaft and the working horizons 16 and 17 open the third system of ramps from horizon 12.

 The position of the openings 22 in the permanent or semi-stationary side of the quarry is arbitrary. It can be automobile or railway exits, conveyor trenches or semi-trenches, etc.

 The mining operations of the proposed method is as follows.

 The rock mass from the excavation faces of working horizons 3 and 4 is transported along the ramp system 19 to the day surface, and from the bottoms of horizons 10 and 11, the rock mass is transported through the ramp system, along the transport berm left in the constant side at horizon 6, and then on the opening workings of a constant board. Similarly, the rock mass is transported from horizons 16 and 17 using a transport berm at horizon 12 in the permanent side of the quarry.

 In FIG. 1 presents the situation of mining, when conditions are created for the beginning of the separation of horizons 5 and 12 of the temporarily idle side. During the production of mass explosions for loosening the ledge at horizon 5, the ejection of rock mass to the lower horizons will be limited by the barrier shaft of horizon 6. Thus, the slope of the temporarily idle side formed from the ledges of horizons 7, 8, 9 and 10 will not be filled up with blasted rock mass, which ensures the continuous functioning of the system of exits from horizon 6 and the safety of bringing the ledge of horizon 11 into a temporarily inoperative position.

 Similar to the above, horizon spacing 12 is performed.

 After the separation of horizon 5 proceed to the separation of horizon 6 temporarily idle side. In this case, the rock from the barrier shaft can be shipped together with the explosive rock mass of the ledge, thereby eliminating the barrier shaft at horizon 6.

 But during this period, there is no need to preserve the barrier shaft, because on horizon 6 a working platform will be formed with a width that excludes the release of blasted material to the lower horizons of the temporarily idle side during the explosion of the next drill hole.

 After the ledge on horizon 6 is brought into a temporarily inoperative position (Fig. 2), the barrier shaft 25 will be formed again on this horizon, which will make it possible to proceed with the spacing of the temporarily idle side formed from horizons 1, 2, 3, 4, 5, and 6.

 Since, according to the recommended method, barrier shafts are formed at intervals in depth equal to the height of sections of the temporarily idle side, in this case, through 6 horizons, then by the beginning of horizon separation 7, the barrier shaft at horizon 12 will be formed in new position 25. In this case, the ramp system horizon 12 to horizon 17 is eliminated, the transport berm 21 on the horizon 12 of the constant side is extended by the step size of the movement of the section of the temporarily idle side and under the protection of the barrier shaft in the new position of the follower They are just forming a new system of exits from horizon 12 to lower working horizons.

 The economic efficiency of the proposed method is provided by reducing the current stripping ratio, which is achieved by increasing the resulting angle of inclination of the sides of the quarry. The functional relationship of the distinguishing features of the invention with the goal is as follows.

 If the barrier shafts are formed at intervals not equal to the height of the sections of the temporarily idle side, but shorter intervals, this will lead to a decrease in the resulting angle of inclination of the working side of the quarry.

 Since the sections of the temporarily idle side are formed under the protection of the barrage shafts, only safety berms equal to one third of the ledge height, for example 5 m with a ledge height of 15 m, can be left on the horizon of the parcels. The width of the berm on the horizon of the barrage shaft is 20-30 m, and, if you reduce the interval between these horizons, for example, by half, this will lead to a flattening of the resulting angle of inclination of the working side of the quarry, and therefore to an increase in the current stripping ratio.

 If the barrier walls are formed at intervals greater than the height of the sections of the temporarily idle side, this does not provide the conditions for safe mining, which is unacceptable. If, for example, the barrier shaft 25 (Fig. 2) is formed not on horizon 12, but on horizon 14, then to ensure safe mining operations at horizons 12 and 13, it will be necessary to leave wide areas of 30-40 m, on which rock collapse will accumulate during mass explosions, which in turn will also lead to a decrease in the resulting angle of inclination of the working side of the quarry.

 If transport berms are arranged on the permanent side of the quarry not at the level of the barrier walls, but at other elevations, this will lead to a flattening of the inclination angle of the constant side of the quarry, an increase in the average over the quarry and the current stripping ratio. If, for example, the transport berm 21 (Fig. 1) is left not on horizon 12, but on horizon 10, then it will be possible to transport rock mass only from horizons 10 and 11. After moving the barrier shaft at horizon 12 to a new position 25 ( figure 2), the transport connection of horizons 12-17 with the transport berm at horizon 10 is interrupted, since when the temporary out-of-flight side is separated, its slope will be bombarded with blasted rock mass. Thus, in addition to the transport berm at horizon 10, it will be necessary to leave the transport berm at horizon 12, which will lead to a flattening angle of inclination of the constant side of the quarry.

 Failure to form a system of exits in the working area of the quarry from the horizons of the barrage shafts to lower working horizons within a depth interval equal to the height of the sections of the temporarily idle side will make it impossible to transport the rock mass from the horizons of the specified interval to the nearest transport berma located in a constant board. In this case, transport berms in the permanent side of the quarry will need to be left on almost every horizon, which will lead to a sharp flattening of the slope of the constant side. It is possible in another way to solve the problem: to divide the working area of the quarry into two parts, in one of which to form the working board in the form of sections of temporarily idle sides, alternating with the working horizons according to their spacing, and in the other to form normal working platforms on all horizons. Then, from each working horizon, there will be a direct exit to the second part of the working area with normal working sites according to the separation of temporarily non-working boards. But at the same time, it is possible to increase the resulting tilt angle of the working board only in one of the parts of the working area, which will lead to an increase in the current stripping ratio in the whole career.

 The analysis allows us to argue that all the distinguishing features of the proposed method are functionally related to the goal, and their implementation in combination with the known features will improve the efficiency of the prototype method.

 The novelty of the proposed method consists in a new procedure for protecting rock horizons block in the process of bringing them into a temporarily inoperative position and opening the working horizons of the block during the separation of the temporarily idle side.

 The invention can be applied both to increase the resulting angle of inclination of the working side of the quarry, represented by the horizons on which working platforms of the calculated width are formed, and to distribute a semi-stationary side with large dimensions in depth and in plan formed on the intermediate circuit, which is especially typical for many major iron ore quarries now.

 In the first case, the implementation of the proposed method is as follows.

 Suppose that the project establishes the possibility and expediency of mining a quarry with sections of a temporarily idle side formed of six ledges.

 The separation of temporarily idle sides is made by two working horizons, i.e. as represented in figures 1 and 2.

 In this situation, the ledge at horizon 1 is stopped, which is the beginning of the formation of the upper section of the temporarily idle side, consisting of horizons 1-6. After bringing the ledge on horizon 6 to a temporarily inoperative position, the barrier shaft is poured on it and horizons 6 and 7 form working platforms of the estimated width (in Fig. 2 this is indicated by a dashed line). Starting from horizon 7, from the lower working horizons, the middle section of the temporarily idle side with the filling of the barrier shaft at horizon 12, etc., is similarly formed.

 After the final formation of all sections of the temporarily idle side stipulated by the project, further quarrying is carried out using the above technology.

 In the second case, when the semi-stationary side is formed on the intermediate contour of the pit, the implementation of the invention is carried out in the reverse order: first, the spacing of horizons 1 and 2 is carried out. After the work platforms of the calculated width are created on these horizons, the ledge at horizon 1 is stopped, which is the beginning of the formation of the upper section of the temporarily idle side.

 After the ledge on horizon 6 is brought into a temporarily inoperative position, the barrier shaft is poured on it and the upper horizons of the formed temporarily inoperative side are spread. At the same time, under the protection of the barrier shaft, further separation of the semi-stationary side on the intermediate circuit is continued with the formation of the middle section of the temporarily idle side, etc.

 Currently, the proposed invention is being implemented in the design documentation developed by the Giprorud Institute for the Koashva quarry of Apatit Production Association.

Claims (1)

 A method for open-pit mining of mineral deposits, including the formation of temporarily idle side sections in the working area of the quarry, the separation of the upper horizons of the temporarily idle side simultaneously with its formation by bringing the temporarily inoperative position below the working horizons, characterized in that barriers are dumped on the horizons of the temporarily idle side shafts for catching rockfall at intervals in depth equal to the height of the sections of the temporarily idle side, and in constant whether temporarily inoperative board career placement on levels of protective suit transport shafts berm with conventions which are disposed on the lower working horizons within the range of a depth equal to the height of the bead portion is temporarily inoperative.

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