RU2260116C1 - Method and device for underground reservoir forming in rock salt - Google Patents

Abstract

FIELD: mining, particularly for building underground reservoirs adapted for liquid and gaseous product storage and for brine extraction through wells.

SUBSTANCE: method involves mounting coaxial outer and central suspension pipe strings with installing central pipe string bottom at underground reservoir bottom; sealing well head; supplying solvent into underground reservoir to be formed through outer suspended pipe string and displacing the resultant brine to ground surface through central pipe string. Channel for brine movement to bottom of central pipe string is formed above insoluble rock deposit present in underground reservoir between lower ends of outer and central pipe strings. Before salt dissolving process shutdown or in the case of oversized insoluble rock ingress in central pipe string bottom solvent is supplied to underground reservoir through central pipe string and brine is displaced through outer one.

EFFECT: facilitated dissolving system actuation, increased operational capabilities and prevention of bridge forming.

2 cl, 1 dwg, 1 ex

Description

The invention relates to the construction in salt deposits of underground tanks for storing liquid and gaseous products, and the extraction of brines through wells.

There is a method of creating an underground reservoir in rock salt deposits through a borehole, which consists in supplying water through a central suspension column to the lower part of the underground reservoir and displacing the brine formed by dissolving the salt through an external suspension column to the surface [A. Furman, M. Beldy M. ., Sokolov I.D. Salt. Production and application in the chemical industry. M., "Chemistry", 1989, pp. 103-112].

A device for implementing this method is two coaxially arranged suspension columns of pipes, while the shoe of the central water supply column is located below the shoe of the external brine lifting column (ibid.).

The disadvantage of this method and device for its implementation is the need for frequent elevations of the central suspension column as a result of the accumulation of sediment of insoluble rocks at the bottom of the tank, precipitating during the dissolution of rock salt and preventing the flow of solvent into the underground tank.

Closest to the claimed solution is a method of creating an underground reservoir in rock salt deposits through a well, including mounting coaxially located outer and central pipe columns, installing a shoe of the central column at the bottom of the underground reservoir, sealing the head of the well, supplying solvent to the underground reservoir through an external suspension column, and the displacement of the resulting brine along the central column to the surface from the bottom of the underground reservoir (ibid.).

A device for implementing this method is known, including a casing string of a borehole pipe, a head, two coaxially located central and external pipe casing pipes for supplying solvent and raising the brine to the surface. The shoe of the central suspended brine lifting column is located below the shoe of the external water supply column (ibid.).

In this method, part of the sediment formed at the bottom of the underground reservoir together with brine is displaced along the central suspension column to the surface.

The disadvantage of the method and device for its implementation is that with a high content of insoluble rocks in rock salt and during stops of water supply to the underground tank, the sediment formed at the bottom of the tank overlaps the lower end of the central column, while the hydraulic connection between the brine in the underground tank is broken and in the central suspension column, which leads to a halt in the dissolution process. In addition, oversized inclusions of insoluble rocks fall inside the central column, which leads to the formation of a cork, sometimes it is necessary to completely dismantle the central suspended column to remove it.

The problem to be solved is to increase the efficiency of the method of creating an underground reservoir with a high content of insoluble rocks in rock salt.

As a result of solving this problem, the following are provided:

- Easy start-up of the system of dissolving rock salt after it stops, which is due to the provision of hydraulic communication between the brine in the created underground reservoir and the brine in the central column, through which it is displaced to the day surface.

- Stable displacement brine capacity, since the accumulation of sediment prevents the increase in hydraulic resistance at the shoe of the central column.

- A stable high concentration of displaced brine, due to the fact that the brine is taken from the underground reservoir near its bottom.

- Eliminating the formation of plugs from insoluble rocks inside the central column, since before stopping the dissolution system, the brine located in the central column is replaced by a solvent, and oversized inclusions of insoluble rock accumulate in the narrowed part of the shoe of the central suspended column and are removed when water is supplied to it.

The essence of the proposed method lies in the fact that in the method of creating an underground reservoir in rock salt deposits through a well, which involves the installation of coaxially located external and central suspended pipe columns, installing the shoe of the central pipe string at the bottom of the underground tank, sealing the head of the well, supplying solvent to the underground a reservoir along an external hanging column of pipes and the displacement of the resulting brine to the surface along the central column, according to the proposed method, between two ends of the outer and central tubular strings suspended create a special channel through which the brine is fed to the central outboard shoe pipe string. Before stopping the process of dissolving rock salt or when oversized inclusions of insoluble rocks get into the shoe of the central hanging pipe string, the solvent is fed into the underground tank through the central hanging pipe string, and the resulting brine is displaced through the external hanging pipe string.

The removal of the brine formed above the sediment of insoluble rocks to the shoe of the central suspension column using a special channel provides a stable hydraulic connection between the solvent supplied to the well and the displaced brine, more intensive erosion and efficient absorption of sediment of insoluble rocks at the shoe of the central suspension pipe string.

When the solvent is fed into the underground tank through the central pipe string and the brine is displaced through the external pipe before the dissolution process stops, or if oversized inclusions of insoluble rocks get into the shoe of the central suspension column, the latter is washed and the said inclusions are removed from the shoe of the central suspension column and suction zone. At the same time, the solvent exiting the central suspension string of the pipes erodes the sediment below the shoe of this column to a depth exceeding the suction zone, thereby eliminating the re-entry of oversized inclusions into the shoe of the central hanging column.

Thus, the combination of the above features provides a solution to the problem of increasing the efficiency of the method of creating an underground reservoir in rock salt.

The implementation of this task is achieved using a device for creating an underground reservoir in rock salt, including a casing string of a well pipe, a head, coaxially located central and external suspension columns of pipes for supplying solvent and raising the brine to the surface, a shoe of a central suspension pipe string. According to the proposed device, an annular tip is coaxially mounted on the lower part of the central hanging pipe string, the inner diameter of which is larger than the external diameter of the central hanging pipe string, and its external diameter is smaller than the internal diameter of the external hanging pipe string. The upper part of the annular tip is perforated.

An annular tip mounted at the end of the central suspension column, the inner diameter of which is larger than the external diameter of the central suspension column of pipes and the outer diameter is smaller than the internal diameter of the external suspension column, allows the central suspension column to be installed together with the tip inside the external suspension column, to supply brine from the underground tank to the central suspension column in the formation of sediment above the shoe of the central suspension pipe string, as well as erosion of sediment in the suction zone Bani shoe at the central suspension pipe string.

The perforated upper part of the annular tip allows the intake of the most saturated brine from the lower part of the underground reservoir above the layer of sediment formed.

Thus, the combination of the above features provides a solution to the problem of increasing the efficiency of creating an underground reservoir in rock salt.

The proposed method of creating an underground reservoir in rock salt and a device for its implementation are illustrated by the diagram in the drawing.

The drawing shows a well 1, equipped with a casing 2, coaxially located external pendant 3 and a central pendant 4, in the lower part of which is installed an annular tip 5, which acts as a channel between the brine located in the underground reservoir 6 and the shoe 7 of the Central pendant 4, with the accumulation of sediment 8 at the bottom of the underground reservoir 6. A shoe 7 of the central suspension column 4 is installed at the bottom of the underground reservoir 6. An annular tip 5 in the upper part is made with perforation 9.

The method is as follows.

When creating an underground reservoir 6, water is supplied to the well 1 through an external suspension pipe string 3 to dissolve the rock salt, and the resulting brine is forced out through the shoe 7 of the central pipe suspension string 4 to the surface. With the accumulation of sediment 8 of insoluble rocks contained in rock salt, at the bottom of the underground reservoir 6, the brine from the lower part of the underground reservoir 6 is directed through the channel formed between the annular tip 5 and the central hanging column of pipes 4, from the underground reservoir 6 to the shoe 7, and the central hanging column of pipes 4 is forced to the surface. In this case, the stream of brine passing through the channel erodes the sediment at shoe 7, and the resulting hydraulic mixture of sediment 8 and brine are forced to the surface along the central suspension pipe string 4.

Before the water supply stops to dissolve the rock salt in the process of creating the underground reservoir 6, water is supplied to the central hanging column of pipes 4 to remove insoluble inclusions from it, which can form a plug. The volume of water supplied must not be less than the volume of the central hanging pipe string 4.

To prevent oversized inclusions of insoluble rocks from entering the shoe 7 of the central suspension string of pipes 4 and the formation of extended plugs inside this string (which can be determined by the increase in water pressure at the head of the well 1 at the mouth of the external suspension string 3 and the pressure drop at the mouth of the central suspension string 4) the shoe 7 can be narrowed or provided with a grill (not shown in the drawing), and water is supplied from above to the central hanging column of pipes 4 with the displacement of the brine from the underground tank 6 through an external hanging stake 3. no narrowed lower end of the central outboard columns or presence lattice prevent ingress of oversized inclusions suspended insoluble rocks into the pipe string, thereby eliminating the formation inside of extended plugs. Oversized inclusions of insoluble rocks are removed by a stream of water from the shoe 7 of the central suspension column 4. The flow of water exiting the shoe 7 erodes sediment 8, while oversized inclusions of insoluble rocks are at a depth of 1-2 m from the shoe 7 of the central suspension column 4 outside the suction zone .

The implementation of the device for implementing the proposed method is shown in the drawing. It includes a well 1 with a casing string of pipes 2, a head (not shown in the drawing), coaxially located external 3 and central 4 with a coaxial annular tip 5, suspended columns of pipes for supplying solvent and raising the brine to the surface when creating an underground tank 6, shoe 7 central a suspended pipe string 4 installed at the bottom of the underground reservoir 6. An annular tip 5 is provided with a perforation 9 in the upper part and is located in the lower part of the central suspended pipe string 4. The diameter of the lower part of the central suspended string nna tubes 4 smaller than the diameter of the central part. The inner diameter of the annular tip 5 is larger than the outer diameter of the central hanging pipe string 4, and its outer diameter is smaller than the inner diameter of the external hanging pipe string 3.

The operation of the device is as follows. Well 1 is equipped with a casing string of pipes 2 and the external 3 and central 4 suspension pipes are installed in it. Water for the dissolution of rock salt is supplied through an external hanging column of pipes 3, and the resulting brine through a shoe 7 along a central hanging column 4 is displaced from the underground reservoir 6 to the surface. In the process of dissolving rock salt, insoluble rocks contained in it in the form of sediment 8 are deposited at the bottom of the underground reservoir 6. As sediment 8 accumulates, brine from the underground reservoir 6 passes through the perforation 9 into the annular tip 5 and erodes sediment 8 at the exit from it. which, together with the brine through the shoe 7, is displaced to the surface through the central suspension column 4. Through perforation 9, the most saturated brine is extracted from the lower part of the underground reservoir 6, while the small size of the perforation (slits 1-3 mm wide) does not allow sediment 8 to form plugs inside the ring tip 5. A narrowed shoe 7 or shoe 7 with a grill made in it prevents the penetration of oversized inclusions of insoluble rocks inside the Central suspension column 4, which prevents the formation of plugs. If oversized inclusions of insoluble rocks get from sediment 8 into the narrowed shoe 7, the latter are removed as described above.

An example of a specific implementation are bench tests of this device for the construction conditions of an underground gas storage. Well 1 drilled from the surface of the earth to rock salt deposits is cased by a pipe 2 with a diameter of 299 mm. An external hanging pipe string 3 with a diameter of 219 mm and a central hanging pipe string 4 with a diameter of 127 mm are coaxially mounted on it.

The central suspension pipe string 4 had a narrowed shoe 7 with an inner diameter of 90 mm and an annular tip 5 with a diameter of 168 mm. The length of the annular tip 5 was 4 m. Perforation 9 of the annular tip 5 is made in the form of slots with a width of 2-3 mm and a length of 20 mm, staggered at a height of 1 m from its lower part to the top. The area of the slits per 1 running meter of the annular tip 5 is equal to 3 areas of the gap between the annular tip 5 and the central column of pipes 4. To increase the efficiency of erosion of sediment 8 by a swirling flow in the gap between the annular tip 5 and the central column of pipes 4, a guide is made in the lower part of the annular tip 5 in the form of three two-turn spirals. Tests showed that during operation of the device, the slurry from sediment 8 and brine rises evenly, while the maximum slurry density reached m: w = 1: 1 with an average density of m: w = 1: 4 ~ 1: 6. The height of sediment 8 above shoe 7 of the central suspension string of pipes 4 during testing reached 3.5 m. During stoppages of the water and subsequent launches of the dissolution system, there were no cases of plugging at shoe 7 and in the central suspension string of pipes 4 during the tests. According to the test results, the device is recommended for industrial use.

Thus, the tests confirm that when using the method of creating an underground reservoir in rock salt and a device for its implementation, the following set of conditions is met:

- A device embodying the claimed invention in its implementation is intended for use in industry, namely, in the construction of underground reservoirs in rock salt and the extraction of brines through wells.

- For the claimed method of creating an underground reservoir in rock salt and a device for its implementation in the form as described in the independent claims, the possibility of its implementation using the means described in the application is confirmed.

- Therefore, the claimed method of creating an underground reservoir in rock salt and a device for its implementation meet the condition of "industrial applicability".

Sourse of information

1. Furman A.A., Beldy M.P., Sokolov I.D. Salt. Production and application in the chemical industry. M., "Chemistry", 1989, pp. 103-112.

Claims (2)

1. A method of creating an underground reservoir in rock salt through a well, including mounting coaxially arranged external and central suspended pipe columns, installing a shoe of a central column at the bottom of the underground tank, sealing the well head, supplying solvent to the underground tank through an external hanging pipe string, and displacing the resulting brine to the surface along the central column, characterized in that a channel is created between the lower ends of the outer and central suspended pipe columns, through which the brine is fed to the ba Shmak of the central suspension pipe string, before stopping the process of dissolving rock salt or when oversized inclusions of insoluble rocks get into the shoe of the central suspension pipe string, the solvent is supplied to the underground tank through the central hanging pipe string, and the resulting brine is displaced through the external hanging pipe string. 2. A device for creating an underground reservoir in rock salt, including a casing string of a borehole pipe, a head, coaxially arranged central and external suspension pipes of pipes for supplying solvent and raising the brine to the surface, a shoe of a central suspension pipe string, characterized in that on the lower part of the central the suspension pipe string is coaxially mounted with an annular tip, the inner diameter of which is larger than the outer diameter of the central suspension pipe string, and the outer diameter is smaller than the outside diameter hinges of the suspended pipe string, while the upper part of the annular tip is perforated.