RU2305771C1 - Method for borehole mining of permafrost sedimentary rock - Google Patents

Abstract

FIELD: mining, particularly mineral mining by hydraulic borehole mining and underground accumulation reservoir construction.

SUBSTANCE: method involves uncovering productive seam 1 with borehole 2; installing water-supply 3, 4, air-supply 5 and sludge lifting 6 pipe strings in the borehole; supplying water from water pool; delivering compressed air; cutting productive seam to create underground chamber 7 by water-and-heat rock breakage and resultant hydromixture lifting to ground surface along with maintenance of predetermined water-air level 8 at productive seam roof in chamber 7 by supplied water and air flow regulation; additionally delivering heated water in borehole 2, wherein heated water rate is less or equal to volumetric flow rate of solid permafrost sedimentary rock to be cut contained in the hydromixture to be lifted. Water from water pool is supplied into underground chamber 7 under lower level of sludge-lifting pipe string 6 at flow rate equal or exceeding water flow rate in above hydromixture.

EFFECT: increased efficiency of permafrost sedimentary rock mining due to extended mining season along with relatively low power inputs.

1 dwg, 1 ex

Description

The proposed technical solution relates to mining and can be used in the development of minerals by the method of downhole hydraulic production and the construction of underground storage tanks.

A known method of downhole hydraulic mining of minerals, including opening a well of a productive formation of minerals, installing a downhole projectile, heating water and supplying it to the downhole projectile, forming an underground flooded chamber by heat and water destroying the rock by an unburied hydromonitor stream, suctioning and hydro-elevating slurred rock of a destroyed rock formation to the surface [1].

The disadvantage of this method is the high energy costs associated with the use of heated water, not only for water-thermal destruction of rocks, but also for hydro-elevator lifting of the destroyed rocks to the surface. In addition, the water-thermal destruction of the rock in the underground chamber with an unburied jet stream is also associated with increased energy consumption due to the low heat transfer in comparison with heat transfer in a flooded chamber.

Closest to the claimed technical solution is a method of borehole development of permafrost placers, including opening a productive formation by a well, installing water supply, air supply and pulp lifting columns in it, supplying water from a ground reservoir and compressed air, working out a productive formation with the formation of an underground chamber by means of water-heat the destruction of rocks and the rise of the resulting slurry of rocks to the surface with the maintenance in the underground chamber of a given level of the air-water interface at the roof and reservoir flow regulation fed water and air [2].

The disadvantage of this method is the low efficiency of water-thermal destruction of frozen rocks by water supplied from a surface water reservoir, which is associated with low temperatures of water heated from solar radiation in the North and a short season with positive temperatures.

The task at hand is to increase the efficiency of the borehole development of permafrost sedimentary rocks by providing the possibility of increasing the length of the production season at relatively low energy costs.

As a result of solving this problem, it is ensured:

- low energy consumption due to the use of cold water both when weighing destroyed rocks in the suction zone, and at the time of raising the hydraulic mixture to the surface;

- the maximum use of the heat of the heated water during thawing of permafrost sedimentary rocks, since the supplied heated water remains in the underground chamber in the interval of the reservoir and is not removed together with the destroyed permafrost sedimentary rocks to the surface.

The essence of the proposed technical solution lies in the fact that in the method of borehole development of permafrost placers, which includes opening a productive formation by a well, installing water supply, air supply and pulp lifting columns in it, supplying water from a reservoir and compressed air, working out a productive formation to form an underground chamber by water -the thermal destruction of rocks and the rise of the resulting slurry to the surface with the maintenance in the underground chamber of a given level of the water-air interface at the roof of the product of the reservoir, by adjusting the flow rate of the supplied water and air, according to the proposed method, additionally heated water is supplied into the well with a flow rate equal to or less than the volumetric flow rate of solid material of the permafrost sediment developed in the raised slurry, and the water is supplied from the reservoir into the underground chamber under the lower level pulp lifting columns of pipes with a flow rate equal to or greater than the flow rate of water in the raised hydraulic mixture.

During the supply of additionally heated water with a flow rate equal to or less than the volumetric flow rate of solid material of the developed permafrost sedimentary rocks contained in the raised slurry, the volume of the rock extracted from the underground chamber is replaced by the same volume of heated water supplied. As a result of this, the heat transfer efficiency between heated water and frozen rock is increased, and heat loss does not occur, since the water level in the underground chamber created in this case does not rise above the top of the reservoir, and the heated water itself is not removed from the underground chamber by airlift.

The injection of water from the reservoir into the underground chamber under the lower level of the pipe lifting string with a flow rate equal to or greater than the flow rate of the recovered slurry of the recoverable rocks allows the sedimentary rocks to be weighed in the soil intake zone to be removed by airlift to the surface without removing additionally heated water from the surface underground chamber. Maintaining the water level in the underground chamber at the top of the reservoir helps increase heat transfer efficiency without reducing the productivity of airlift lifting of permafrost sedimentary rocks. Cold water taken from a reservoir does not participate in heat exchange with frozen rock and is spent only on creating a hydraulic mixture during airlift, which allows mining in winter, thereby prolonging the production season.

Thus, the combination of the above features provides a solution to the problem of increasing the efficiency of the proposed method without increasing energy consumption and with a significant increase in the duration of the mining season.

The proposed method for borehole development of permafrost sedimentary rocks is illustrated by the scheme shown in the drawing.

The drawing shows a productive formation 1 of developed permafrost sedimentary rocks, opened by a well 2, in which the water supply pipes 3 and 4 are mounted for supplying heated and cold water, respectively, the air supply pipe 5 for supplying compressed air to the airlift and the slurry pipe string 6 for lifting the hydraulic mixture developed permafrost sedimentary rocks to the surface. The underground chamber 7 created in the process of these rocks is filled with water to level 8, maintained at the roof 9 of the productive formation 1. At the bottom of the underground chamber 7, a sediment 10 of the destroyed rocks of the productive formation 1 is formed.

The method is as follows.

In accordance with the diagram, the producing formation 1 of the developed permafrost sedimentary rocks is opened by a well 2, into which a water supply pipe string 3, which serves to supply heated water, and a water supply pipe string 4 for supplying cold water from the reservoir, an air supply pipe string 5 for supply, are mounted compressed air into the airlift and pulp lifting pipe string 6 for lifting the slurry of the developed rocks to the surface of the earth.

To heat cold water, water from the pump is piped to a heater (not shown), and then through a water supply pipe string 3 through a well 2, it is pumped into the lower part of the created underground chamber 7. Rising due to natural convection, the heated water gives off heat to the walls of the underground chamber 7 , thawing the rocks of the productive formation 1, while the destroyed dispersed rock settles at the bottom of the underground chamber 7, forming a precipitate 10. Cold water from the reservoir is pumped through a water supply pipe string 4 to the suction zone B species under lower level pulpopodemnoy pipe joint 6 for weighing the sediment 10. When injecting air through the air supply pipes 5 column precipitate weighed 10 rocks pulpopodemnuyu sucked into the pipe string and as the slurry is raised to the surface. Moreover, in the created underground chamber 7, a predetermined position of the water level 8 at the roof 9 of the productive formation 1 is maintained, which is provided by regulating the flow rate of cold water supply through the pipe supply pipe 4. The heated water is supplied through the pipe supply pipe 3 at a rate equal to or less than the volumetric flow rate solid material of developed permafrost sedimentary rocks contained in hydraulic mixtures raised to the surface of the earth, determined using a densitometer or by measuring the mass of the rock at mouth alluvium. With an increase in water level 8 in the created underground chamber 7, the flow rate of cold water is reduced, and with a decrease in level 8, its flow rate is accordingly increased. With a decrease in the concentration of the specified solid material in the raised slurry, the consumption of heated water increases, which increases the thawing capacity of permafrost sedimentary rocks of the productive formation 1.

An example of a specific implementation of the method is the downhole hydraulic production of building sand during the development of permafrost sandy buried sediments.

Productive stratum 1 of permafrost sands with a thickness of 30 m lies under clay deposits with a thickness of 20 m. Stratum 1 is opened with a borehole 2 with a diameter of 300 mm. The above-mentioned pipe columns 3, 4, 5 and 6 are mounted in well 2 from a surface reservoir. Cold water is pumped into a water supply pipe string 4 with a flow rate of 150 m ³ / h and into a heater with a flow rate of 30 m ³ / h, of which at a temperature of 40 ° C heated water is sent to the water supply pipe string 3. Thawing permafrost sand of productive formation 1 is thawed on the walls of the created underground chamber 7 with warm water, while the thawing capacity of the rocks is about 30 m ³ sand per hour. Thawed sand is deposited at the bottom of the underground chamber 7. The sediment 10 of the destroyed sandy rocks is weighed with cold water coming from the pipe supply pipe 4 and suctioned into the pulp lifting pipe string 6. For airlift lifting of the rock slurry through the pipe lifting pipe 6 from the compressor through the pipe air pipe 5 supply compressed air with a flow rate of 25 m ³ / min, while the performance of airlift lift by hydraulic mixture is about 180 m ³ / h. The water level 8 in the created underground chamber 7 is maintained at the roof 9 of the productive formation 1 by regulating the flow of cold water supplied through the water supply pipe string 4. When the water level 8 is increased in the underground chamber 7 above the roof 9 of the productive formation 1, the cold water consumption is reduced, and when reduced level 8 respectively increase.

Information sources

1. Arens V.Zh., Ismagilov B.V., Shpak D.N. Downhole hydraulic mining of solid minerals. M., Nedra, 1980, p.21.

2. Russian Patent No. 2009323, IPC E 21C 45/00, “Method for the borehole development of permafrost placers”, publ. 1994

Claims (1)

The method of borehole development of permafrost sedimentary rocks, including opening a productive formation by a well, installing a water supply, air supply and pulp-lifting pipe string in it, supplying water from a reservoir and compressed air, developing a productive formation with the formation of an underground chamber by heat and water destruction of the rocks and lifting the resulting hydraulic mixture to surface, with maintaining in the underground chamber a predetermined level of water-air separation at the roof of the reservoir by controlling the flow rate of the supplied water and air a, characterized in that the well is supplied with additionally heated water with a flow rate equal to or less than the volumetric flow rate of solid material of the developed permafrost sedimentary rocks contained in the raised hydraulic mixture, and the water is supplied from the reservoir into the underground chamber under the lower level of the pulp-lifting pipe string with a flow rate of equal to or greater than the flow rate of water in the raised hydraulic mixture.