RU2327041C2 - Bore-hole erlift bullet for mineral resourses hydromining - Google Patents

Abstract

FIELD: mining engineering.

SUBSTANCE: bullet consists of external pulplifting pipe section 1 fitted with seal assemblers and inner water-and air delivering pipes 2 and 4, which upper ends are output from pulplifting pipes, lower end of water delivering pipe is fitted with checker 3, and lower end of air delivering pipe is fixed with sprayer 5. Inside pulplifting and air delivering pipes addition sectional pipe is installed 6 for delivering of warmed water and steam for defrostation of formations, which ends are derived beyond pulplifting pipe.

EFFECT: effectiveness improvement of excavation and working of frozen sedimentary strata.

5 cl, 3 dwg, 1 ex

Description

The invention relates to mining and, in particular, to devices for downhole hydraulic mining.

Known borehole airlift projectile for hydraulic mining of minerals, consisting of parallel-located slurry, air and water supply pipes [1].

However, with a parallel arrangement of pipes, less than 50% of the cross-sectional area of the production well is used, which reduces the efficiency of the airlift projectile.

Also known is a downhole airlift projectile for hydraulic mining of minerals from frozen buried placers, consisting of sections of the external pulp lifting pipe and internal water and air supply pipes provided with docking assemblies, the upper ends of which are outside the pulp lifting pipe, the lower end of the water supply pipe is equipped with a nozzle, and the lower end is provided with a nozzle air supply pipe - nozzle [2].

The disadvantage of this device is that the process of thawing frozen rocks, the supply of heated water is carried out through an internal water supply pipe, while part of the water at the outlet of the hydraulic nozzle is sucked into an external pulp-lifting pipe and then, rising to the surface, it is no longer spent on thawing the rocks, which reduces the efficiency of the airlift projectile.

The technical problem in the development of the inventive downhole airlift projectile for hydraulic mining is to increase the efficiency of production and development of frozen sedimentary rocks by providing a separate supply of heated water or steam for thawing rocks and cold water - for weighing settled sedimentary rocks in the suction zone.

At the same time, heat losses are reduced, and the time for joining its sections during installation in the well is reduced, and the reliability of the device as a whole is increased.

The solution to this problem is achieved by using a borehole airlift projectile for hydraulic mining of minerals, consisting of sections of the external pulp pipe and internal water and air pipes equipped with docking units, the upper ends of which are outside the pulp pipe. The lower end of the water supply pipe is equipped with a nozzle, and the lower end of the air supply pipe is equipped with a nozzle. According to the proposed technical solution, an additional sectional pipe is installed inside the pulp-lifting pipe, the ends of which are pulled out of the pulp-lifting pipe.

The difference of the claimed device also lies in the fact that the additional sectional pipe is provided with thermal insulation.

Another difference of the device is expressed in the fact that an additional sectional pipe is installed inside the air supply pipe.

A distinctive feature of the device is also that in the connecting nodes of the pipe of the upper sections are rigidly interconnected.

In addition, in the connecting nodes of each section, at least one of the internal pipes of the device is equipped with a threaded connection.

The difference between the device is also that the pipe equipped with a threaded connection is connected with the remaining internal pipes with the possibility of its axial rotation.

The installation of an additional sectional pipe inside the pulp-lifting pipe, the upper and lower ends of which are outside the pulp-lifting pipe, allows separate supply of heated water or steam, consumed for thawing rocks, and cold water, necessary for weighing minerals in the suction zone.

Providing additional sectional pipe with thermal insulation reduces heat loss during the movement of heated water or steam along the borehole airlift projectile.

When installing an additional sectional tube inside the air supply pipe, the reduction of heat loss during the advancement of heated water or steam along the borehole airlift shell can be achieved without the use of heat insulating material. In addition, with a decrease in the surface of the pipes inside the slurry pipe, the hydraulic resistance decreases and thereby the efficiency of the airlift lift of the mineral increases.

Providing a rigid connection between the pipes in the docking nodes of the upper sections of the device can reduce the time of their joining and at the same time achieve a fixed position of the pipes in the docking station with a more reliable sealing of pipes.

The creation of a threaded connection in the docking nodes, at least on one of the inner pipes of each section, increases the reliability of the joining of the section pipes, provides the necessary tightness and rigidity of the pipe connection, in addition, it allows the use of commercially available pipes with threaded joints when creating the design of a downhole airlift projectile.

The possibility of axial rotation of a sectional pipe equipped with a threaded connection allows the use of a combined joint of sections, in which part of the inner pipes are joined by means of rubber o-rings, and one of the inner pipes is threaded to create a rigid connection between all the inner pipes. As a result, the time is reduced and the reliability of the connection of the pipe sections of the downhole airlift projectile is ensured.

Figure 1, 2 and 3 schematically shows embodiments of an airlift projectile for downhole hydraulic mining.

Figure 1 - an embodiment of an airlift projectile, providing for the installation of an additional sectional tube inside the pulp-lifting pipe.

Figure 2 is an embodiment of an airlift projectile, in accordance with which an additional sectional pipe is installed inside the air supply pipe.

Figure 3 shows a section of the inner pipes with a docking unit.

The airlift projectile for downhole hydraulic mining of minerals according to the images in figures 1, 2 and 3 includes an external pulp lift pipe 1, an internal water supply pipe 2 with a hydraulic nozzle 3 at the lower end of this pipe, and an air supply pipe 4 with an air nozzle 5 at the lower end of the pipe 4. The upper ends of the water supply 2 and air supply 4 pipes are displayed outside the pulp lifting pipe 1 through its walls. Inside the slurry pipe 1, an additional sectional pipe 6 is installed, the upper and lower ends of which are outside the walls of the slurry pipe 1.

In accordance with an embodiment of the downhole airlift projectile shown in FIG. 1, the internal cavity of the additional sectional pipe 6 is provided with thermal insulation 7. The sections of the pulp-lifting pipe 1 are rigidly interconnected by means of a fixing element 8 shown in FIGS. 1, 2. The fixing element 8 is made in the form of a quick disconnect lock connection or a threaded connection (coupling). Air supply 4, additional section 6 and water supply 2 pipes of the upper sections in the docking nodes are rigidly interconnected by an insert 9 and a ring 10 (FIGS. 2, 3), allowing axial rotation of the water supply pipe 2. The sections of the water supply pipe 2 are rigidly joined by means of a threaded connection 11 , which is equipped with a water supply pipe 2 (Fig. 3), and in the docking nodes of the sections of the air supply 4 and the additional sectional 6 pipes, rubber rings 12 are installed to ensure sealing of the pipe joint.

In accordance with the image of the downhole airlift projectile in FIG. 2, an additional sectional pipe 6 can also be installed inside the air supply pipe 4 with the ends of the pipe 6 being brought out of the walls of the pipe 4. With the indicated arrangement of the device’s internal pipes, pipe 6 insulation is not required.

The operation of the airlift projectile shown in figure 1 (the first embodiment of the device) is as follows. Initially, during the development of frozen mineral deposits, for example, sandy deposits, a well is drilled from the surface of the earth (not shown in Fig. 1), into which a borehole airlift projectile is mounted section by section. To this end, the lowest section of the airlift projectile is lowered into the well (Fig. 3). This section is pre-suspended on the head of the casing string of the well pipes (not shown in FIG. 1). The second section of the device is docked in the well with an installed lower section. In the upper part of the second section, by means of inserts 9, pulp lifting 1, water supply 2, air supply 4 and additional water supply 6 pipes are rigidly interconnected. The sealing of pipes 2, 4 and 6 when they are docked is carried out using rubber rings 12. The sealing of the pulp lifting pipe 1 is also carried out by means of rubber rings 12 and a fixing element 8, made in the form of a quick-release lock connection. After docking the first two sections of the downhole airlift projectile, both of them sink into the well to a depth corresponding to the length of the second section. Similarly, the remaining sections of the downhole airlift projection are joined. Upon completion of installation of the device, the upper end of the water supply pipe 2 is connected to the pipeline laid from the liquid pump (not shown in Figs. 1-3), the upper end of the air supply pipe 4 is connected to the pipeline laid from the compressor (not shown in Figs. 1-3 ) The upper end of the additional sectional pipe 6 is connected to a pipeline leading to a heating installation (not shown).

The heated water from the heating installation into the well (not shown in FIG. 1) is supplied through an additional sectional pipe 6 of the downhole airlift projectile, in which heated water or steam leaves the pulp-lifting pipe 1 through the lower end of the additional sectional pipe 6. As a result of heat exchange of warm water and frozen sand, the latter are thawed with melting sand settling in the lower part of the borehole airlift projectile. At the same time, compressed air pumped from the compressor through the air supply pipe 4 through the air nozzle 5 is fed into the pulp-lifting pipe 1, where as a result a water-air hydraulic mixture is formed, which is raised through the pipe 1 to the surface by suction of sand and water through the lower end of this pipe. Cold water coming from the pump through the water supply pipe 2, when passing through the hydraulic nozzle 3, forms a stream weighing the settled sand below the slurry pipe 1, facilitating its absorption. With a relatively large length of the additional sectional pipe 6, it is provided with thermal insulation 7, for example, in the form of an internal polyethylene pipe. Thermal insulation 7 reduces heat transfer between heated water and a cold slurry moving through a slurry pipe 1, which saves heat energy consumption by a downhole airlift projectile.

In order to improve the performance of the inventive device by increasing the useful cross section of the lifting pipe 1, reducing hydraulic resistance when lifting the hydraulic mixture and reducing costs when installing the device without the use of insulation 7, a second embodiment of the downhole airlift projectile shown in FIG. 2 can be used, in accordance with with which an additional sectional pipe 6 is installed inside the air supply pipe 4. At the same time, the slurry pipe 1 is provided with a fixing element 8 holding sleeve with threaded connection. The lower ends of the upper sections of the air supply 4 and the additional water supply 6 of the pipes are equipped with rubber sealing rings 12, and the upper ends of these pipes are rigidly interconnected by an insert 9. A ring 10 is fixed to the air supply pipe 4, allowing axial rotation of the water supply pipe 2. The sections of the water supply pipe 2 are provided threaded connection 11.

The operation of the device according to the second embodiment is as follows.

When joining sections of a borehole airlift projectile, first, the internal pipes installed in the slurry pipe 1 are connected. By means of the threaded connection 11 of the water supply pipe 2, a rigid connection of the internal air supply 4 and the additional water supply 6 of the pipe is ensured. After joining the inner pipes 2, 4 and 6, the section of the pulp-lifting pipe 1 is connected to the fixing element 8.

Thawing of frozen rocks is carried out by supplying heated water or steam through an additional sectional pipe 6 located inside the air supply pipe 4. Compressed air supplied from the compressor usually has a high temperature, of the order of 50-70 ° C, and low thermal conductivity. Therefore, when the air moves through the air supply pipe 4, the heat loss of the water flowing through the additional water supply pipe 6 is reduced. Through threaded connections of the slurry lifting 1 and water supply 2 pipes, the rigidity of the borehole airlift projectile is ensured, which also allows the use of commercially available pipes in its manufacture.

An example of a practical implementation of the claimed device is a borehole airlift projectile for hydro production of sand from frozen sandy deposits (Fig. 2). It contains a slurry pipe 1 with a diameter of 273 mm, inside which a water pipe 2 with a diameter of 108 mm is installed with a hydromonitor nozzle 3 at the lower end, and an air pipe 4 with a diameter of 108 mm and an air nozzle 5. An additional water pipe 6 with a diameter of 64 mm is installed inside the air pipe 4. .

Water heated to a temperature of 50 ° with a flow rate of 40 m ³ / h is supplied through an additional water supply pipe 6, and cold water with a flow rate of 150 m ³ / h is supplied through a water supply pipe 2. The compressed air from the compressor with a flow rate of 20 m ³ / min is pumped through the air supply pipe 4. Raising the slurry to the surface is carried out with a capacity of 150 m ³ / h and the issuance of sand with a capacity of about 40 m ³ / h.

Information sources

1. Shpak D.N. Hydro-mining of separately-grained minerals through wells with an unstable roof. “The first Soviet-Yugoslav symposium on the problem of downhole hydraulic technology. IPGR, April 1991, p.29

2. Arena V.Zh., Bryukhovetsky O.S., Khcheyan G.Kh. Downhole coal mining. M., 1995, p. 85.

Claims (5)

1. A borehole airlift projectile for hydraulic mining of minerals, consisting of sections of the external pulp pipe and internal water and air supply pipes provided with docking assemblies, the upper ends of which are pulled out of the pulp pipe, the lower end of the water supply pipe is equipped with a nozzle, and the lower end of the air supply pipe is a nozzle, characterized in that an additional sectional pipe for supplying heated water or steam for thawing rocks, the ends of which Dena beyond pulpopodemnoy pipe. 2. Downhole airlift shell according to claim 1, characterized in that the additional sectional pipe is provided with thermal insulation. 3. Downhole airlift projectile according to claim 1, characterized in that in the connecting nodes of the pipe of the upper sections are rigidly interconnected. 4. Downhole airlift shell according to claim 1, characterized in that in the connecting nodes of each section, at least one of the inner pipes is provided with a threaded connection. 5. Downhole airlift shell according to claim 4, characterized in that the pipe provided with a threaded connection is connected with the remaining internal pipes with the possibility of axial rotation.

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