RU51107U1 - Borehole Hydro-Production Complex - Google Patents

Abstract

The utility model relates to the mining industry and can be used in downhole hydraulic production of waterlogged minerals. The objective of the utility model is to expand the arsenal of well-known hydro-mining complexes to ensure mining operations in complex flooded hydrogeological conditions. Achievement of such technical results as the implementation of the purpose of the hydro-production complex in complex flooded hydro-geological conditions, an increase in the length of the jet stream of the monitor, expansion of the borehole hydro-production area for denser flooded minerals, a multiple increase in the diameter of production chambers and extraction of minerals from each chamber, ensuring controllability of the hydraulic production process, increasing the reliability of hydraulic wells in the developed fields was made possible thanks to that a downhole hydro-production complex, including at least one equipped, hydro-production well with a hydro-production chamber located in the reservoir and at least one control well, additionally includes at least one dewatering well, equipped with at least one filter and a submersible pump, this filter is installed in the area of productive and / or underlying formations, and the submersible pump is located at a depth that provides the opportunity to lower the groundwater level to the lower boundary of the hydro production th camera.

Description

The utility model relates to the mining industry and can be used in downhole hydraulic production of waterlogged minerals.

A well-known complex of downhole hydraulic mining of minerals, which includes a number of wells: hydraulic and auxiliary, and technical means of ore destruction and lifting the ore mass to the surface. The disadvantage of this technical solution is the low efficiency of the hydraulic monitor in the working chamber filled with groundwater, due to a drop in the pressure energy of the working agent stream to almost zero already at a distance of 0.5-0.7 m from the nozzle.

The complex allows you to open a productive formation with a vertical well equipped with a hydraulic elevator for delivering slurry to the surface (Arena V.Zh. et al. “Experience in borehole hydraulic ore mining at the Shamraevsky site of KMA”, Mining Journal No. 5, 1995 [1]; Zhurin S.N. , Kolesnikov V.I., Streltsov V.I. “Geomechanical monitoring of flooded massifs”, Publishing House “Natural Resources.” M., 1997.

It is also known a device comprising a nozzle mounted on an internal flexible column (AS No. 1828922). In working condition, the nozzle extends and increases the radius of erosion. But the flexibility of the retractable sleeves limits the extension of the nozzle by 1.5 m, therefore, the efficiency of the hydraulic monitor increases slightly.

The closest and selected as a prototype is a hydro-mining complex, including a device according to A.S. No. 972099. The specified device contains a production well, opening the reservoir, passed with a borehole formation and underlying rocks, an electric pump, which is located below the reservoir, a casing with a packer,

installed above the top of the reservoir between the borehole wall and the casing, a hydraulic mining device, lowered into the interval of the developed formation, as well as a pulp-lifting column, air duct, electric cable and a spillway.

The development of the reservoir by the specified complex is as follows.

After the descent of the water monitoring device into the interval of the reservoir, a pump is turned on that pumps water from the annulus and delivers it to nozzles: destructive minerals. The resulting hydraulic mixture is sucked into the slurry pipe. Then air is supplied into the air duct, which is fed through the nozzle to the pulp-lifting column, to the packer and to the production chamber, displacing water from it. To form a mining chamber, the hydraulic mining apparatus is rotated about its axis. The return of used water occurs by gravity to the overburden.

The disadvantages of the prototype based on the device according to A.S. No. 972099 is a number of limiting conditions for its use, which practically do not occur in the natural environment, and the complexity of the technical solution, namely:

- rocks covering the reservoir must be impervious to air or allow extremely low air losses, otherwise water will not be displaced by air from the production chamber;

- the reservoir must also have extremely low air permeability, since air will flow into the reservoir, and the hydraulic monitor will remain flooded;

- the inflow of water into the working chamber from the reservoir in the amount of injection through the hydraulic monitor and the loosening nozzle nozzle must be "equal to the volume of water used by the hydraulic elevator;

- with less water entering the chamber, air will enter the pump through the suction lift of the elevator. With a greater flow of water, the nozzle will be flooded. Managing the balance of water in the chamber is extremely difficult;

- the water pressure in the reservoir must be less than the air pressure, otherwise air will not enter the chamber and the packer;

- the fundamental solution and the design of the device, providing for its rotation with the simultaneous supply of air to the packer, are very difficult technically.

The objective of the utility model is to develop a hydro-mining complex to ensure hydro-mining operations in flooded "rocks in difficult hydrogeological conditions.

Technical results that can be obtained by implementing the inventive utility model are:

- implementation of the purpose of the hydro-mining complex in hydrogeological conditions;

- an increase in the length of the jet of the jet monitor;

- expanding the scope of borehole hydraulic production for denser watered minerals;

- a multiple increase in the diameter of mining chambers and extraction of minerals from each chamber;

- ensuring the controllability of the hydraulic production process;

- improving the reliability of the hydro-mining complex;

- reduction in the number of oil production wells in the developed fields.

The solution of this problem and the achievement of the above results was made possible due to the fact that the downhole hydro-production complex, which includes at least one equipped hydro-production well with a hydro-production chamber located in the reservoir

and at least one control well, additionally includes at least one dewatering well, equipped with at least one filter and a submersible pump, while the filter is installed in the zone of productive and / or underlying rocks, and the submersible pump is located at a depth that provides the possibility of lowering the level groundwater to the lower boundary of the hydraulic chamber.

The use of the claimed combination of essential features is aimed at reducing jet energy losses by ensuring the operation of the hydromonitor in the air, while it is possible to increase the jet length by more than 10 times compared with the jet length obtained when the hydromonitor is operated in a water-filled chamber.

The utility model is illustrated by the “Vertical section” figure, which shows hydro-production and water-lowering wells located in the reservoir and equipped with a drainage tank, a centrifugal pump, a pipeline, and a depression funnel.

The inventive borehole hydro-production complex includes hydro-production 1 wells, hydro-production shells 2, a water-lowering 3 well, a productive 4 formation, covering sediments 5, and an underlying 6 formation.

The water-reducing 3 well is equipped with a production casing 7 with a filter 8, which is installed in the interval of the productive 4 and the underlying 6 layers, a “blind” pipe 9 installed in the lower part of the underlying 6 layer, a submersible pump 10, which is located below the productive 4 layer - in the underlying 6 the reservoir and the lifting stand 11. In order to improve the hydraulic connection of the production chamber 12 with a dewatering 3 well in tight permeable rocks in the interval between the faces of the production 1 (before drilling) and dewatering boiling 3 wells in the last performed torpedoing (known technology). Water production wells 1 are located at a distance C. from the water-reducing well 3. The value of l

is determined in accordance with the characteristic of the overburden, the stability of the ceiling (not shown in FIG.) of the hydro-mining chamber 12. The auxiliary control wells in FIG. 1 are not shown. In practice, they are located to the left and right of the water-reducing 3 wells.

The complex also includes a centrifugal pump 13, which supplies water pumped out by a water-reducing 3 well through a pipe 14 from the drainage tank 15. In FIG. Also shown is a depression funnel 16 of the surface of the underground water in the drained rock mass, and hydro-mining chambers 12.

The operation of the downhole hydraulic complex is as follows.

Depending on the field development system, the location of hydro production 1 and water-lowering 3 wells relative to each other may change.

With a linear development system, water production 1 and water-reducing 3 wells are arranged in one linear row, wells can alternate in a row: water-lowering 3 through one, two or more water-producing 1 wells, depending on the size of the created depression funnel by one water-reducing 3 well and the size of the water-producing chamber, determined depending on the permissible exposure of the ceiling.

It is possible to arrange a water-reducing 3 wells in the center with a circular arrangement of 1 hydraulic wells. With areal development of the field, it is possible to arrange water-lowering 3 wells along the perimeter, and hydro-mining 1 wells inside the contoured area.

In all cases, the condition for achieving a decrease in groundwater level to the lower boundary of the hydraulic mining chambers must be fulfilled.

A water-lowering 3 well is being constructed, opening the reservoir 4 and spreading 6 to the design depth, providing

water reduction in the productive 4 stratum with the formation of a depressed funnel 16 to its sole.

At the estimated distance l, 1 hydraulic wells are constructed on both sides of the water-reducing 3 wells. In a dewatering 3 well, a submersible pump 10 is mounted and groundwater is pumped out from the reservoir into the catchment 15. In the production wells 1, the production shells 2 are mounted.

When working out the formation "bottom-up", the work includes hydro production 1 wells, when the surface of the depression funnel 16 will be at the soil of the worked formation. Hydro-mining shells 2 supply water flowing through line 14 at high pressure. Hydrojet jets 17 destroy the minerals of a productive 4 layer and with a hydro-mining projectile 2, the pulp rises to the surface.

The operation of the dewatering 3 wells maintains the groundwater level in the reservoir 4 so that the jet 17 operates in air. With the increase of the hydro-mining chamber 12 in diameter and reaching its design dimensions (from the condition of stability of the ceiling), the process of mining the mineral reservoir is completed. Water production wells 1 are liquidated or used as filling wells, and a water-lowering 3 well, depending on the state of water reduction in adjacent blocks, can continue to be operated in the design mode.

The practical use of the claimed method is illustrated by an example of a hydro-mining complex.

Example.

In the deposit of phosphate sands, a productive layer with an average thickness of 12 m lies at a depth of 51 to 63 m. In the roof of the sands there is a layer of plastic weakly permeable chalks that play the role of an upper confinement.

The soil of the reservoir is represented by silt with a thickness of about 2 meters and marls, the upper part of the thickness of which is up to 10 m is slightly fissured and flooded. The waters of phosphate sands, siltstones and marls are hydraulically connected and form a single aquifer, the natural level of which is at a depth of 9 m. The total thickness of the aquifer is 24 m. The average values of the filtration and piezoconductivity coefficients are 2.6 m / day and 1.8 · 10, respectively. ⁵ m ² / day

Phosphate sands are mainly fine-grained feldspar-quartz with glauconite and an admixture of cementing carbonate and silt material. Sands are dense, weakly cemented, the limit of resistance to uniaxial compression does not exceed 2 MPa.

The hydro-production complex includes two vertical hydro-production wells, which extend to a depth of 63 m. The diameter of the casing string overlapping the over-thickness is 426 mm. Productive sands are 393 mm in diameter. Wells are equipped with hydromonitor and pulp lifting devices.

The layer is worked out in a bottom-up direction with two intervals (set-ups) of 6 m each.

At a distance of 2 meters from the axis of the hydraulic wells is a water-reducing well. To the roof of the Cretaceous to a depth of 23-25 m, the well passes through the sandy-clay thickness and is fixed by pipes with a diameter of 426 mm. Below to a depth of 75 m, tunneling is carried out in one diameter with fastening by casing pipes with a diameter of 325 mm. In the interval of the aquifer, the casing is perforated and equipped with a strainer.

The submersible pump is lowered to a depth of 70 m. With the minimum necessary lowering of the groundwater level in the hydraulic chamber 54 m, the steady flow to the water-reducing well (according to the Dupuis formula) is 152 m ³ / h, therefore, the well is equipped with a submersible pump

ETsV brand 12-160-140. The required decrease in water level - to the soil of the reservoir in production wells is achieved in less than one day. After the necessary decrease in the water level in production wells, hydraulic monitors are included in the work. As a working agent, drainage water accumulated in the drive is used.

The pressure at the outlet of the nozzle of the nozzle of the hydraulic monitor is 40 m.v.st. The length of the jet 17 in the unburied chamber is 9.5 m. The maximum diameter of the production chamber, m is 20.

In a flooded chamber using a retractable nozzle. the diameter of the working chamber does not exceed 4 meters. From this it follows that the hydroproduction of phosphate sands under the protection of water reduction makes it possible to increase the size of the hydroproduction chambers by 5 times and to extract ≈7000 tons of phosphate sands from two simultaneously operating chambers.

For reasons of maintaining the stability of the ceilings and preventing the collapse of the roof of the chambers, a further increase in the size of the production chambers is not advisable in plan.

To control the development of chambers at a distance of ~ 10 m from the axis of each hydro production well, drilling of control wells is provided.

Thus, as can be seen from the example, the inventive hydraulic production complex works efficiently in complex flooded hydrogeological conditions, allows to increase the length of the jet from the hydraulic monitor by 10 times, increase the volume of the production chamber by five times, and accordingly reduce the number of hydraulic wells.

Reliability of work and controllability of the operation of the hydro-mining complex is achieved through regular observations of control wells.

Claims (1)

A downhole hydraulic production complex comprising at least one equipped hydro production well with a hydro production chamber located in the reservoir and at least one control well, characterized in that it further includes at least one water-reducing well equipped with at least one filter and a submersible pump, the filter is installed in the zone of productive and / or underlying formations, and the submersible pump is located at a depth that provides the possibility of lowering the groundwater level to the lower level Itza gidrodobychnoy camera.