RU2261331C2 - Open-cast mining method - Google Patents

Abstract

FIELD: mining industry, particularly for open-cast mining of steeply inclined, even vertical, laterally bounded ore body, for instance diamondiferous kimberlite pipe under flooded conditions.

SUBSTANCE: method involves forming hydraulic-mining dump; opening quarry field by pit excavation; filling the pit with water; installing floating pump dredger in plant with cutter; performing rock excavation at quarry field; transporting the obtained rock to ground surface through pulp conveying line and conveying dead rock to hydraulic-mining pump. The quarry field is previously zoned into horizontal layers (horizons) and quarry field development is performed by cutting horizontal layers in top-bottom direction so that water level is lowered as layers are excavated and water surface is maintained at current production horizon level.

EFFECT: reduced power and cost inputs for field dewatering.

3 cl, 2 dwg

Description

The invention relates to the mining industry and can be used in open pit mining of mineral deposits with steeply inclined, to vertical, fall of ore bodies limited in terms of planes, for example, diamondiferous kimberlite pipes, in conditions of intensive watering.

There is a method of open-pit mining of mineral deposits, according to which a hydraulic dump is constructed, a quarry field is opened with a pit, a quarry is filled with water and a floating dredging device with a cultivator is mounted in it, a quarry field is excavated, the resulting rock mass is transported to the surface with a slurry pipeline and waste rock is placed into a hydraulic dump [ 1].

The known method can be applied in difficult natural and mining conditions for the development of diamondiferous kimberlite pipes folded by low strength kimberlites.

However, the above method requires the use of a large working body (boom or other device that delivers the working body of the dredging device to the bottom under water (when using a floating dredging device with a cultivator), or a scoop frame and a scoop chain (in case of dragee development)). This leads to an increase in the overall dimensions and metal consumption of the equipment, loss of maneuverability and reliability in operation, which, ultimately, leads to a loss in development efficiency.

In addition, the known method leads to flooding the career field and requires alteration of standard equipment manufactured by the industry.

The technical result to which this technical solution is directed is to drain the open pit rocks and prepare the surrounding massif for the reconstruction of the open pit and move to the next stage of its development using development systems without filling the workings with water simultaneously with the development of the field, which leads to a reduction in energy consumption and capital expenditures for drainage of the field and ensures the development of the field in a short time and with minimal initial investment As well as in the use of standard equipment without alteration.

This result is achieved due to the fact that in the method of open-pit mining of mineral deposits, according to which a hydraulic dump is constructed, the quarry field is opened by a pit, the quarry is filled with water and a floating dredging device with a cultivator is mounted in it, a quarry field is excavated, and the resulting rock mass is transported to the surface slurry pipeline and the placement of waste rock in a hydraulic dump, previously the quarry field is marked into horizontal layers (horizons) and a quarry floor is excavated I have horizontal layers from top to bottom, and while working out the layers, they maintain a water mirror at the roof level of the current operational horizon. The water balance to maintain the water mirror at the level of the operational horizon is maintained by returning water from the hydraulic dump to the quarry. To work out the next layer, its cutting is carried out by a pit, which is then expanded by a floating dredging device, and the development of horizontal layers is carried out by continuous excavation by a system of casts.

Figure 1 shows a General view of the quarry in plan and the location of the dredging device and equipment; figure 2 is a section along aa.

The implementation of the proposed method is as follows. Preliminarily, studies of the physicomechanical properties of covering, enclosing and ore mass rocks are carried out and their ability to be developed in the flood zone by hydromechanization methods is tested because of their low strength and poor connectivity.

Taking into account the studies of the hydrogeological conditions of the deposit and the physicomechanical characteristics of the rocks of the open pit field 1, the open pit mining on the ore body is carried out by underwater excavation of the rock with a floating dredging device 2 equipped with a cultivator (for example, a milling type) combined with a submersible pump. Taking into account the characteristics of the applied suction pump, the quarry field is marked into horizontal layers (horizons) 4, 5 and the quarry field 1 is excavated with horizontal layers from top to bottom. To work out the next layer, its tapping is carried out by a pit 6, which is then expanded by sinking with the same dredging projectile 2 of a split mine, which ensures further development of the horizon. The development of the current operational horizon is carried out by calls 7, similar to dragee moves. The placement of moves is chosen so as to ensure complete excavation of the rock mass over the entire area of the quarry or part thereof at a given mark. The rock mass is transported through a slurry line 8 to a hydraulic dump (not shown in the drawing) - when developing overlapping or enclosing rocks, or to a concentration plant - when developing an ore mass. Before storage or enrichment, the hydraulic mixture is thickened, drain water in the volumes necessary to maintain the required water level in the quarry is returned for reuse in closed circulation mode.

The transition to the development of the next current operational horizontal layer (operational horizon) is carried out with a simultaneous decrease in the water level in the quarry, and during the development of the layers, a water mirror 9 is maintained at the roof level 10 of the current operational horizon 5.

Thus, the water level in the quarry decreases in accordance with a decrease in mining, providing optimal working conditions for the dredging device, and a dredging device with a cultivator performs the functions of not only a mining machine developing a quarry, but also a pumping unit that provides pumping water that interferes with mining operations up to draining the quarry in the last stages of the operation of the dredging device.

The side of the quarry 11 is rebuilt with the formation of horizontal safety berm safety, providing safe working conditions located below the dredging device 2 and spaced from each other in height of the operational horizon. The stability of the side will increase with the decrease in water and the drainage of the surrounding rock mass quarry.

The transport connection of the dredging device with the surface is carried out along an inclined trench laid outside the quarry, then carried out on board the quarry and deepened as the mining operations deepen. On the same trench, a slurry line 8 is laid, along which rock mass is transported overboard the quarry. As the depth of the quarry and, accordingly, the height of the pulp rise along the slurry line, pumping pumping stations are built.

As a result, mining is lowered to a depth corresponding to the boundary of the transition from weak ores to ore with high strength characteristics, requiring other development methods. Due to the drainage of the field, which is the result of developing the irrigated part of the claimed method, it becomes prepared for the effective use of other, “dry” development systems to continue open pit mining on it.

The implementation of the proposed method, for example, the development of one of the diamond-bearing pipes in the north-west of the European part of Russia, is as follows.

The field is located in a flat wetland. The thickness of the overlying deposits varies from 30 to 60 meters. They are represented by unbound sandy loam and loam with rare interlayers of sandy composition. The host rocks to a depth of 200 meters are weak sandstones, the strength parameters of which gradually increase with depth. The entire thickness from the surface is intensely flooded. The ore body is a vertically lying funnel-shaped massif, to a depth of 130-150 meters, composed of low-strength effusion-sedimentary kimberlite rocks of the crater portion of the deposit. Having the original natural low strength, these rocks in the aquatic environment lose it even more. The composition of kimberlites changes below, the intrusive autolithic kimberlite breccia with significantly higher strength characteristics becomes predominant. The hydromechanized quarry development method is thus possible to apply to a depth of 150 meters.

The quarry is laid directly above the ore body. When preparing mining operations, they organize the water supply system of the dredging device. At the first stages of the development of the quarry, water inflow from the developed massif will be insignificant, and the need for mining operations in water for transportation and laying in the dump of the rock mass will be great. Therefore, use surface water sources for the covered needs of the quarry for water (usually they are). In this case, it is not necessary to create a system for protecting mining operations from flooding (as in traditional development methods). Refusal of water protection measures at the first stage of quarry development, their transfer to later dates (with natural optimization in terms of volume and cost of work) significantly reduces the cost and time of preparatory work, has a noticeable effect on improving the economy of the mining enterprise.

Also, an essential component of the preparatory phase is the arrangement of a hydraulic dump. To store the slurry in the selected area and to prevent contaminants from entering the surrounding topography, a dam from filtering soils is being constructed at the site, means are provided for thickening the incoming slurry (the simplest are devices using hydrocyclones), means for washing down hydraulic dumps, and also returning drainage water to the rock section. During the operation of the mining complex, the water that accumulates in the dump tank pond will either return to the quarry or, after additional treatment to the MPC, will be discharged into the river network depending on the requirements for maintaining the water balance.

Transport and other communications that ensure the connection of the dredging device with the surface (delivery of people, fuel, spare parts, materials) are laid along an inclined trench, laid behind the contour of the quarry and going on board at a level determined by the level of the water mirror in the quarry. The trench is deepened as mining operations deepen. When the quarry reaches the sole of the overlying deposits, the direction of the trench changes. Further, it also passes with a depression along the open side of the quarry. In the same trench, lines of slurry pipelines are laid along which the slurry is pumped for its subsequent transfer to a hydraulic dump or for enrichment. With the deepening of mining operations and, accordingly, an increase in the elevation of the pulp along the slurry pipelines, transfer pumping stations are installed. The pulp is supplied from the dredging device to the onshore stationary pulp line by means of a flexible floating sand line articulated both with the onshore pulp line and with the dredging device.

Quarry development is carried out horizontally by horizontal ledges. The height of the step is selected at a rate of 55-60% of the maximum development depth, determined by the technical passport of the dredging device. With a passport operating depth of the dredging device of 18 meters, the height of the ledge is determined at 10 meters. To ensure continuity of work and to prevent the development of massive discharges of water from the landfill during the transition to the next horizon, the quarries are divided into several parts, at least two halves, each of which is worked out by horizontal layers - ledges, the height of which differs from adjacent ledges of the second half of the quarry at half the height of the ledge. The deepening of mining operations with semi-steps allows the discharge of water from the landfill also in layers with the height of the lowering of the water layer after working out the horizon in one half of the quarry and moving to the second half, which is also half the height of the operational horizon. Thus, the total amount of water accumulated during the development of the current horizon and subject to discharge during the transition to the next horizon is half as much in volume as during the development of the entire pit area with one ledge. In addition, a decrease in the water level in the quarry can be carried out gradually, during the entire period of development of the horizon in this half of the quarry, since the total development depth during the transition of the dredging device to the mining of the next step is within the passport digging depth of the dredging device.

The development of the next horizon of each of the quarry halves begins with the construction of an opening excavation - a foundation pit, the dimensions of which allow the dredging device to begin systematic mining of the horizon. Pits for opening the exploitation horizons of each of the quarry halves are laid, as a rule, on opposite flanks of the quarry. Each of the halves of the quarry is worked out sequentially after the complete completion of the other half.

The adopted development system is a continuous excavation of the rock mass at the project boundaries of the quarry with a system of adjacent longitudinal, adjacent transverse (relative to the long axis of the quarry field), combined moves of the dredging device. The adjacent location of the faces provides the maximum width of the entry, which helps to minimize the loss of time for stops during turns of the dredging device and the transfer of the floating slurry line. Upon transition to the underlying horizon along the outer contour of the quarry, a safety berm is formed, which ensures safe working conditions of the dredging device in the instrument zone while lowering mining operations.

After the pit reaches the soles of the deposits overlapping the kimberlite pipe, mining operations according to the scheme described above are concentrated in the contours of the ore body, which become the natural boundaries of the quarry developed by the dredging device at these depths. The technologies for developing the ore mass and deepening it remain the same as in the upper horizons. Only the direction of pumping the rock mass changes to the beneficiation plant, where it undergoes the appropriate stages of dehydration, classification and other operations of ore preparation, beneficiation with storage of tailing tailings in the tailings of the refinery. The cycle of reverse water supply for mining operations with the regulation of water balance is preserved here.

Thus, the proposed technical solution will allow:

- To drain the rocks of the quarry field. The surrounding mountain range becomes prepared for the reconstruction of the quarry and the transition to the next stage of its development using development systems without filling the workings with water.

- Proceed to the development of the field, despite the difficult natural and mining conditions, in a short time and with minimal initial investment.

- Reduce energy and capital costs for draining the field.

- Apply standard equipment without modifying it (that is, at no additional cost).

Sourse of information

1. RF patent No. 2081321, MKI 7 E 21 C 41/26, dated 10.09.97.

Claims (3)

1. A method of open-pit mining of mineral deposits, according to which a hydraulic dump is constructed, a quarry field is opened with a pit, a quarry is filled with water and a floating dredging device with a cultivator is mounted in it, a quarry field is excavated, the resulting rock mass is transported to the surface with a slurry pipeline and waste rock is put into a hydraulic dump characterized in that the quarry field is previously marked into horizontal layers (horizons) and the quarry field is excavated with horizontal layers of light xy down with decreasing water levels after working off layers, maintain the water at the mirror roof current operational horizon. 2. The method of open development of mineral deposits according to claim 1, characterized in that the water balance to maintain a water mirror at the level of the operational horizon is maintained by returning water from the hydraulic dump to the quarry. 3. The method of open-pit mining of mineral deposits according to claim 1, characterized in that for the development of the next layer, it is pitted with a pit, which is then expanded, and the development of horizontal layers is carried out by continuous excavation by a floating dredging device with a cultivator with an entry system.

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