RU2465405C2 - Drainage method of open pit edges by means of systems of combined drainage devices - Google Patents

Abstract

FIELD: mining.

SUBSTANCE: drainage method of open pit edges by means of systems of combined drainage devices involves system of combined drainage devices arranged from the side of the open pit bench normally to the edge at soil of water-bearing horizon and consisting of horizontal branch of drain hole and the branch that is close to vertical position, which are equipped with flexible filter. Length of horizontal part is determined considering the entry way value and technical capabilities of the used drilling equipment. Change-over of horizontal branch of the device to vertical position is performed by means of bottom-hole motor and diverting devices. Length of vertical part of combined device is determined depending on capacity of drained water-bearing horizon; therefore, sinking of vertical branch of drainage device ends after the working face enters the rocks of waterproof roof of drained formation. Drilling of combined drainage device in incompetent rocks, for example, sands is performed in step-by-step horizontal part of the shaft under protection of "blind" inventory column of casing pipes, and then removed pipes; sinking of vertical branch of drainage device is performed using self-decomposing or hydrolysed polyacrylonitrile drilling fluids in order to provide the stability of its walls. After sinking of vertical part of the shaft is completed, rock-destructing tool is disconnected and left in solid mass, and bottom-hole motor is removed along shaft of combined device, which is fixed with filter. Drainage water is discharged via the system of the trenches near the edges.

EFFECT: reduction of drilling volumes of drain holes; improvement of reliability of drainage systems, stability of edges of open pits and safety of mining operations; reduction of material consumption and costs for drainage of open pit edges.

3 dwg

Description

The invention relates to the field of development of flooded mineral deposits in an open way.

From the modern technical level known surface method of drainage pits. The most common is a dual-circuit arrangement of drainage devices (Fig. 1), [Kravchuk SV, Kuzkin B.C., Ponomarenko Yu.V. and other Handbook on drainage of rocks. M .: Nedra, 1984; Oksanich I.F., Beresnev B.C., Gordon A.B. and others. Drainage of deposits during the construction of iron ore enterprises. M .: Nedra, 1977], which includes an external obstruction drainage circuit 1, consisting of a line of water-reducing wells that are constructed along the perimeter of the quarry or along the most watered part of the side. The inner (second) circuit 2 may include instrument drainage ditches or a system of horizontal drainage wells defined from the ledges into the quarry of the normal plan of the base of the slope. The depression surface 3 of groundwater in this case is formed under the influence of drainage devices of both circuits. The second drainage circuit is designed: to intercept the groundwater leakage through the external drainage circuit, to reduce hydrostatic weighing and hydrodynamic pressure of the leakage water, the height of leaching to the slope, which is necessary to prevent the development of a suffusion process, sweeping and other negative geological phenomena, and ultimately to ensure the necessary stability of the rock mass array and the safety of mining operations.

This widely used method of protecting open pit mining using dewatering well systems and predominantly horizontal wells has a number of significant disadvantages, which include:

- the need to perform drainage work at two levels - on the surface on the outside of the quarry and inside the quarry on one (or several) ledges;

- application of various types of drilling equipment when performing drainage operations;

- equipment for dewatering wells with submersible pumps;

- a large number of simultaneously operated pumps, which reduces the reliability of the protective system;

- the need to provide access roads to drainage circuits;

- the need for sustainable energy supply and maintenance of water-reducing wells;

- construction of a drainage water drainage system at both levels;

- the danger of destruction (damage) of water-reducing wells when moving mining and transport equipment and when the sides of the quarry are spaced apart;

- the need for drilling at now developing fields of water-reducing wells of considerable depth;

- the complexity of the design of water-reducing wells, crossing most often the layered thickness of the overburden, containing several aquifers;

- the need to leave a column of water in the water-reducing wells to create normal operating conditions (cooling) of pumping equipment, which creates conditions for an increase in groundwater penetration through the barrier installation and generally reduces its drainage effect;

- the possibility of penetration from the surface through the mouth of dewatering wells of various kinds of pollution into the aquifers intersected by dewatering wells, which necessitates the implementation of waterproofing works;

- a significant amount of repair work during the operation of water-reducing wells.

The above-described drainage system for opencast mining, based on the use of two different types of drainage devices, is selected as a prototype of the claimed invention for drainage of quarries and sections using systems from new combined drainage devices. The use of combined drainage devices allows the drainage of the sides of the quarries to carry out a single-circuit drainage system, devoid of the most significant drawbacks related to the prototype.

Technical results that can be obtained using the proposed drainage device:

- transition to a single-circuit drainage system for draining the sides of quarries;

- refusal to use water-reducing wells at the operational stage, characterized by a complex design and significant drilling depths;

- improving the reliability and technical efficiency of drainage systems and simplifying their operation and in connection with the abandonment of the use of borehole submersible pumps;

- increasing the stability of the sides of the quarries, the safety of mining operations, the possibility of increasing the angles of the offsets of ledges;

- trouble-free operation of drainage systems;

- reduction in electricity consumption;

- elimination of the possibility of contaminants entering clean drainage water, since combined devices do not reach the surface, which solves the problem of groundwater protection.

- and, finally, improving the economic performance of drainage pits.

The solution of the problem and the achievement of the above results became possible due to the fact that the dehumidification of the rock mass array is proposed to be carried out by a system of new drainage devices.

A new type of drainage device 4 is formed as a result of the combination fusion of a vertical water-reducing well with a horizontal drainage well laid normally from the ledge on the pit side near the soil of the aquifer, as shown in Fig. 2.

The transition to the use of combined drainage devices is carried out after opening the split trench and the priority mining site, carried out under the protection of the traditional barrage system, made in the form of a linear series of water-reducing wells and tool ditches (trenches). From this moment, the construction of new water-reducing wells is not carried out. In the future, in parallel with the development of mining, a circuit is constructed from combined drainage devices.

A new drainage device is drilled at the base of the ledge normally on the quarry side, directly at the soil of the drained aquifer.

In order to prevent siltation of wells by rock particles penetrating the filter, the wells pass at an angle of 2-3 ° to the horizon.

After sinking the horizontal part of the drainage device, the well is smoothly moved to a close vertical position.

Known difficulties are drilling in loose, unstable sands. Proceeding from this, the horizontal part of the well passes, for example, with the ULB-130M drilling rig under the protection of a “deaf” inventory casing. The transition to the vertical part of the combined drainage device is carried out using a downhole motor delivered to the bottom through a working casing string on drill pipes. A ring mounted on the filter column is put on the engine. This ring rests on a ring welded to the downhole motor, which makes it possible to move the filter string along with the downhole motor. The inner diameter of the filter column exceeds the outer diameter of the engine. At the same time, the diameter of the rock cutting tool connected to the engine by an easily released sub must exceed the diameter of the drawn filter column. This will allow, after reaching a predetermined length of the well, to free the engine and to freely remove the drill pipes from the well through the filter string. Then the working (casing) string is removed.

The stability of the walls of the borehole and the reduction of the friction forces of the drill and casing strings during drilling will be ensured by flushing fluid based on self-dissolving, or hypane, solutions that create an elastic crust on the walls of the borehole that breaks down during pumping.

The destruction of the destroyed rock during drilling is carried out by a flow of flushing fluid supplied by the pump to the drill pipe string.

Well bending is carried out through the use of a downhole motor and deflecting devices:

- diverter type P-1;

- turbine diverter type OTC and others [Kalinin A.G., Levitsky A.Z. Technology for drilling exploratory wells for liquid and gaseous minerals. M .: Nedra, 1988]. The selection of the deflecting device is made in accordance with the specific geological and technical conditions of drilling.

Drilling up in the vertical direction is carried out until the complete intersection of the drained aquifer, i.e. the length of the vertical part of the device is determined depending on the thickness of the drained aquifer. Well penetration is completed after the bottom of the combined well enters the rocks of the water-resistant roof of the drained horizon.

Drainage water is discharged through the system of gutters to the central pumping station at the worked out horizon.

The construction of the proposed drainage devices of a new type is carried out in stages. First, for example, the installation of ULB-130M passes the horizontal part of the device to the design depth, set taking into account the size of the run-in, followed by the fit of the filter and removing the “blank” inventory casing string. Drilling of the ascending part of the device is carried out using a downhole motor, with the help of which a flexible (synthetic) filter is stretched along the borehole, the diameter of which should be 2-4 inches larger than the diameter of the downhole motor. Drilling is carried out with a tip whose diameter exceeds the diameter of the filter by 2 ".

The most difficult to carry out drilling in loose unstable rocks, for example in flooded sands. In these cases, in the process of drilling the vertical part of the combined drainage device, self-dissolving, or hypane, drilling fluids are used to ensure the stability of the barrel walls [D. Bashkatov et al. Handbook of water well drilling. M .: Nedra, 1979].

Drilling is completed in water-resistant stable rocks that overlap the drained aquifer. After the sinking of the vertical branch of the drainage device, the drilling tool is disconnected and left in the array, the downhole motor is removed by the combined well bore fixed by the filter.

For the construction of combined drainage devices, you can use foreign special drilling rigs manufactured in Germany and the USA.

The practical use of the combined drainage device is shown by the example of drainage of the open pit side at the Prioskolsky iron ore deposit (Designed Prioskolsky GOK).

Six aquifers are identified in the section of the Prioskolskoye field: the modern alluvial aquifer (alN), the Turonian-Cognac aquifer (K ₂ tk), the Albian-Cenomanian (Kal-s), the Jurassic aquifer (J), the Middle Upper Devonian aquifer ( D _2-3 ) and the Archean-Proterozoic aquifer (Ar-Pr).

The most watery, sustained in terms of thickness and distribution is the Alb-Cenomanian aquifer (Kal-s). Lithologically, it is represented by fine- and medium-grained sands, in the lower part of the section - coarse-grained sands with inclusions of pebbles. The lower aquifers of the horizon are Jurassic clays with a thickness of 2-4 m. The thickness of the horizon varies from 27 to 30 m. The section of the deposit is shown in Fig. 3.

The horizon’s waters are pressure head, the head over the field’s area varies from 17 m to 35 m. The filtration properties of the horizon are characterized by water conductivity values from 150 to 500 m ² / cit. The coefficient of piezoconductivity ~ 4 · 10 ³ m ² / day.

It is planned to open the Alb-Cenomanian sands with two ledges. The main problems of ensuring the stability of the sides are associated with the drainage of the sand of the horizon. For these purposes, it is necessary to provide for the implementation of a set of drainage measures. At the stage of construction water reduction in the priority area, a traditional linear system of water reducing wells is provided. At the operation stage, it is advisable to provide a system of combined drainage devices, which are laid at the roof of sandy Jurassic clays.

On idle sides, the length of the horizontal part of the combined well is assigned equal to 50 m, then the well is transferred to a vertical or close position, as shown in Fig.2 and Fig.3. Upward drilling is carried out before the Cretaceous opening of the Turonian-Cognac horizon, i.e. about 40 m. The distance between adjacent combined wells is determined to be 30-40 m. According to the results of enlarged hydrodynamic calculations, the established flow rate of one interacting combined well is ~ 1050 m ³ / day, the flow out rate groundwater in the area between two adjacent wells does not exceed 48 m ³ / day, which does not have a significant effect on reducing the overall stability of the sands of the Alb-Cenomanian horizon in slopes.

Claims (1)

The method of draining the sides of quarries using combined drainage systems, including a system of combined drainage devices laid on the ledge of the quarry normally aboard the aquifer soil and consisting of horizontal and close to vertical position drainage well branches equipped with a flexible filter, the length of the horizontal part being determined taking into account the size of the entry and the technical capabilities of the used drilling equipment, the translation of the horizontal branch of the device into vert The vertical position is carried out using a downhole motor and deflecting devices, the length of the vertical part of the combined device is determined depending on the power of the drained aquifer, therefore, the vertical branch of the drainage device is completed after the face has entered the rocks of the waterproof roof of the drained formation, drilling of the combined drainage device in unstable rocks, for example, in sand, they are performed in a phased-horizontal part of the trunk under the protection of a “deaf” inventory th casing string, then extracted pipes, the vertical branch of the drainage device is drilled to ensure the stability of its walls using self-decaying or gypsum drilling fluids, after the vertical part of the shaft has been drilled, the rock cutting tool is disconnected and left in the array, and the downhole motor is removed along the barrel fixed by the filter combined device, drainage water is carried out according to the system of gutters.

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