RU2382176C1 - Underground equipment with device for cleaning of settling well of methane-coal hole during its development and maintenance - Google Patents

Abstract

FIELD: mining.

SUBSTANCE: underground equipment includes assembly of borehole pump descended into hole using production tubing. Steady bush is located in production string below holing zone. Mechanism of compensation of axial displacement of assembly of borehole pump is connected to sludge trap by its lower end, and by upper end - to mentioned assembly through tail filter. Sludge trap in the form of hollow casing with bottom, open from above, is installed airtight on steady bush by its upper part. Underground equipment is located in production string below holing zone after descending into hole and airtight installation of sludge trap by its upper part on steady bush.

EFFECT: speeding and simplification of process of installation and removal of sludge trap due to exclusion of jobs related to round trip of fishing tool, possibility of creation of more considerable pressure drawdown on productive stratum, that is especially important for methane-coal holes during their development and maintenance.

6 cl, 3 dwg

Description

The invention relates to the mining industry and can be used in the development and operation of wells equipped with submersible rod pumps and intended, in particular, for the production of hydrocarbons, for example, methane from coal seams.

It is known that wells designed to produce methane from coal seams are being built with a sump. This sump, whose length is usually 50-80 m, is a section of the wellbore located under the opened productive coal seams. The main purpose of the sump is the accumulation of mechanical impurities in it, coming together with formation water and low-pressure gas from coal seams, in addition, the sump can serve as a location for the layout of underground equipment. The composition of the latter, in addition to the submersible sucker rod pump, includes a downhole gas separator, an anti-flap anchor, a filter shank, drainage and non-return valves. As a rule, exposed coal seams and sump drilled below the interval of their placement are blocked by a production string, which is then cemented. After perforation of productive coal seams, the latter, in the overwhelming majority of cases, undergo hydraulic fracturing in order to further stimulate their gas recovery. Cracks formed as a result of hydraulic fracturing are fixed with the help of proppant, which, together with the process fluid, is pumped into the coal seams.

The process of subsequent pumping of produced water from a methane-coal wellbore is accompanied by a significant amount of various mechanical impurities (mainly proppant, as well as particles of coal, rock, cement, etc.). The removal of the largest amount of mechanical impurities is observed at the initial stage of pumping formation water from the wellbore, over time, the intensity of this phenomenon gradually decreases. The accumulation of mechanical impurities in the well sump worsens the operating conditions of the submersible pump, and at a certain point makes it impossible. In this case, the pumping out of formation water is stopped and the well begins to prepare for underground repairs associated with cleaning the sump from mechanical impurities accumulated in it. In a methane-coal well, they try to carry out these repair works without organizing a flushing, so as not to impair the filtration characteristics of the exposed coal seams. For this reason, various types of baits are usually used to remove mechanical impurities from the sump of a methane coal well. Often for high-quality sump cleaning, multiple trips to the wellbore are required. In general, repair work takes a fairly long period of time, because before they are completed, the methane-gas well must be pre-plugged. Only after that it is allowed to proceed to the extraction of the elevator column with underground equipment. After lifting, the underground equipment is inspected and necessary serviced, and in some cases, individual components are replaced. After completion of repair work, the underground equipment is again lowered into the wellbore, and the process of pumping formation water resumes.

A device is known for removing mechanical impurities from a wellbore [SU 137851, 1961], which is made in the form of a plugged in the lower part of the pipe, to the upper end of which is attached a conical socket. An elastic sealing cuff is fixed on the upper end of the bell. Using a gripping unit, lowered into the wellbore on a cable, the device is placed on the bottom before the start of the operation of the well. Various mechanical impurities coming from the reservoir together with the fluid gradually accumulate inside the device. After filling the device with mechanical impurities, it is removed to the surface for cleaning.

The disadvantages of the known device are the complexity of its installation and lifting using cable technology, since when moving the device inside the production casing, the effect of pistoning occurs.

Closest to the proposed technical solution (ie, the prototype) is a device for cleaning the bottom of the well during operation [RU 2212521, 2003], which includes underground equipment consisting of a submersible pump, lowered on an elevator string, tail pipes with a filter (t ie filter-shank), a removable sludge trap in the form of a hollow cylinder with a bottom, as well as a support sleeve for installing and sealing the sludge trap inside the production casing.

The disadvantages of the prototype include the complexity and duration of the sequential installation in the well of a sludge trap, tail pipes with a filter, the layout of the submersible pump and their subsequent removal from the well in the reverse sequence of operations, as well as the need to use a special fishing tool.

The objective of the invention is the creation of such underground equipment with a device for cleaning the sump of the well, which would ensure the removal of mechanical impurities accumulated in the sump during one lift of the underground equipment, would not require the use of a special fishing tool for both installation and extraction of elements of underground equipment, and it would be able to be placed in the production string below the perforation zone.

The solution of this problem allows us to obtain a technical result, which is expressed in the acceleration and simplification of the installation and extraction of the sludge trap with mechanical impurities from the methane-hole due to the exclusion of operations associated with tripping of the fishing tool (for installing the sludge trap, then tail pipes with a filter and their extraction, respectively).

Another technical result is the ability to create a deeper depression on the reservoir, which is especially important for methane wells in the process of their development and operation.

The problem is solved, and the technical result is achieved by the fact that the underground equipment with a device for cleaning the sump of the well during its development and operation, including the layout of the submersible pump, lowered into the well on the lift string, a support sleeve located in the production string below the perforation zone, a sludge trap in the form of a hollow body with a bottom open at the top, made with the possibility of tight installation with its upper part on the support sleeve, and the filter shank, equipped with a com sensation of the axial movement of the submersible pump layout connected by the lower end to the sludge trap and the upper end to the submersible pump layout through the filter shank, and is arranged to be placed in the production string below the perforation zone after being lowered into the well and the sludge trap is sealed with its upper part on the support sleeve.

Contributes to the achievement of the technical result that:

- the mechanism for compensating the axial movement of the submersible pump assembly is connected by the lower end to the sludge trap, and the upper end to the submersible pump assembly through the filter shank by hinge assemblies, the hinge assembly connecting the lower end of the axial displacement compensation mechanism of the submersible pump assembly to the sludge trap, contains rods attached their free ends to the top of the sludge trap;

- the layout of the submersible pump, lowered into the well on the elevator string, includes sequentially attached to it in the direction from top to bottom, an anti-turnaround mechanical armature and a gas separator.

It is advisable that a check valve be placed in the bottom of the hollow body (sludge trap) open at the top.

In a particular embodiment, the support sleeve has a conical seat, and the upper part of the hollow body open from above is an annular outer protrusion with a conical lateral surface corresponding to the conical seat of the support sleeve, the lower part of the hollow body open from above is made in the form of a truncated cone.

The compensation mechanism for the axial displacement of the submersible pump layout in a particular case is made in the form of a concentric nozzle having a hydraulic connection with the outer space and a rod forming a limited movable connection, with an inner annular protrusion at one end of the nozzle, the other end plugged, and the rod has an outer annular protrusion for interacting with the inner annular protrusion of the pipe in the extended position of the connection.

The essence of the invention is illustrated by the description and drawings. In Fig.1 shows a General view of underground equipment installed inside the production casing of the well, Fig.2 is a General view of the sludge trap installed inside the production casing on the support sleeve, Fig.3 is a mechanism for compensating the axial movement of the layout of the submersible pump.

From practical experience in the extraction of methane from coal seams, it is known that the composition of the underground equipment includes the layout of a submersible pump, lowered into the well, which usually includes (in the direction from bottom to top): filter shank 1, downhole gas separator 2, mechanical counter-hole anchor 3 and a submersible sucker rod pump 4. In addition, the drainage valve 5 can be included in the composition of the underground equipment. The layout of the underground equipment is lowered into the methane-well bore using an elevator column 6.

The wellbore is blocked by a cemented production casing 7, in which perforation channels 8 are made against the interval of productive coal seams. Using submersible pump 4, produced water is pumped from the wellbore to the surface along the inner channel of the lift string 6. During the development and operation of the methane-coal well, the formation water level is maintained at a mark located below the perforation channels 8 in the production casing 7. This creates the necessary depression on productive coal seams, which makes it possible to develop a methane desorption process in them. To the lower end of the filter shank 1, a compensation mechanism 9 for the axial displacement of the arrangement of the submersible pump 4 and a sludge trap 10 are sequentially connected. The latter serves to capture and accumulate various mechanical impurities that enter the wellbore from productive coal seams. The sludge trap 10 is made in the form of an elongated open hollow body from above with a bottom 11. The lower part of the elongated open hollow body from the top (sludge trap 10) is made in the form of a truncated cone, has the shape of a truncated cone, and a check valve is installed in the bottom 11, made, for example, in the form saddles overlapped with a ball element. The body of the sludge trap 10, in fact, includes a cylindrical part that becomes conical. Sludge trap 10, in particular, the cylindrical part of its body, for example, can be composed of tubing (or casing) pipes screwed together. The upper part of the elongated open from above the hollow body (sludge trap 10) has an annular outer protrusion 12 with a conical outer side surface.

The compensation mechanism 9 provides the possibility of reciprocating axial movement of the sludge trap 10 relative to the layout of the submersible pump 4, in particular, the filter shank 1, as well as rotation around their common longitudinal axis.

The compensation mechanism 9 is connected by the upper end to the arrangement of the submersible pump 4 through the filter shank 1, and the lower end is connected to the sludge trap 10 by the hinge assemblies 13 and 14. Moreover, the hinge unit 14 connecting the lower end of the compensation mechanism 9 to the sludge trap 10 contains thrusts 15 connected their free ends to the upper part of the sludge trap 10.

In the particular case, the compensation mechanism 9 can be made in the form of a nozzle 16 and a rod 17 concentrically placed between themselves, which form a limitedly movable connection (telescopic). One end of the pipe 16 to which the hinge assembly 13 is connected is muffled, and the other (opposite) end is connected to the inner ring protrusion 18. The hinge assembly 14 is connected to one of the ends of the rod 17, and the outer ring protrusion 19 is made at the other end. When the telescopic connection is in the extended (extended) position, the annular protrusions 18 and 19, respectively, of the pipe 16 and the rod 17 interact with each other. The hydraulic connection of the pipe 16 with the external space is ensured by the presence of through channels in the walls of the pipe 16, which provide the possibility of unimpeded flow of fluid in the internal cavity of the telescopic connection with the mutual axial movement of the pipe 16 and the rod 17.

In the inner channel of the production casing 7 there is a support sleeve 20 with a tapered seat corresponding to the conical lateral surface of the annular outer protrusion 12. The support sleeve 20 is installed in the calculated place of the production string 7 during the construction of the well, for example, instead of one of the couplings 8, because it has connecting threaded parts are the same as for the coupling. At the same time, the section of the production casing 7 located below the installation location of the indicated supporting sleeve 20 can be made of casing pipes of both normal and reduced diameter (taking into account the maximum outer diameter of the sludge trap 10).

In the bottom of the open, hollow body - sludge trap 10, a check valve is placed, for example, a ball 21, including a seat, a locking member and a stopper limiter.

The proposed equipment works as follows.

Sludge trap 10 is placed on the mouth, attached to the compensation mechanism 9 and through the filter shank 1 connected to the assembled layout of the submersible pump 4, which on the lift pipes 6 are lowered into the well.

In the process of lowering the listed equipment into the well, the compensation mechanism 9 is in a stretched position. The non-return valve 21, installed in the lower part of the sludge trap 10, allows free flow of liquid during the descent. The mass of the launched underground equipment is monitored at the wellhead using a hydraulic weight indicator (GIV).

When approaching the sludge trap 10 to the support sleeve 20, the descent rate of the elevator column 6 is reduced. The landing of the sludge trap 10 on the support sleeve 20 is characterized by a corresponding decrease in the mass of the underground equipment, which is fixed at the wellhead according to the GIV.

The compensation mechanism 9, which is in the extended position, after placing the annular external protrusion 12 of the sludge trap 10 on the support sleeve 20, provides the ability to perform operations related to the installation (engagement) of the back-door armature 3 inside the production casing 7. As a rule, for reliable installation of the mechanical armature 3 rotate the elevator column 6 (half a turn clockwise) while moving it down.

After the completion of work related to the descent of the string of pump rods, sealing of the mouth, installation of the surface drive of the submersible pump 2, etc., the process of pumping the fluid from the barrel of the methane hole is started.

Mechanical impurities in the process of pumping liquid at the stages of development and operation of a methane-coal well gradually accumulate inside the sludge trap 10, without falling into the sump of the well. Due to this, there is no need for repair work related to cleaning the sump of the well from mechanical impurities.

The extraction to the surface of the underground equipment together with the compensation mechanism 9 and the sludge trap 10 is carried out in the reverse order, while the compensation mechanism 9 provides the ability to perform operations related to the removal (uncoupling) of the anti-gate armature 3 from the production casing 7.

Raised to the surface of the sludge trap 10 is cleaned of mechanical impurities or replaced by empty. After that, the sludge trap 10, the compensation mechanism 9 and the underground equipment on the elevator column 6 are lowered again into the well. Then, the above sequence of operations is performed again and the process of developing or operating a methane-coal well is resumed.

Claims (6)

1. Underground equipment with a device for cleaning the sump of the well during its development and operation, including the layout of the submersible pump, lowered into the well on the lift string, a support sleeve located in the production string below the perforation zone, a sludge trap in the form of a hollow body with a bottom open on top, made with the possibility of tight installation with its upper part on the support sleeve, and a filter shank, characterized in that it is equipped with a mechanism for compensating the axial movement of the submersible assembly of the pump, connected by the lower end to the sludge trap, and the upper end - with the layout of the submersible pump through the filter shank, and is arranged to be placed in the production string below the perforation zone after being lowered into the well and the sludge trap is sealed with its upper part on the supporting sleeve. 2. Underground equipment according to claim 1, characterized in that the mechanism for compensating the axial movement of the submersible pump assembly is connected by the lower end to the sludge trap and the upper end to the submersible pump assembly through the filter shank by hinged assemblies, the hinged assembly connecting the lower end of the compensation mechanism axial movement of the layout of the submersible pump with the sludge trap, contains rods attached by their free ends to the upper part of the sludge trap. 3. Underground equipment according to claim 1, characterized in that the layout of the submersible pump, lowered into the well on an elevator string, includes a counter-turnaround mechanical armature and a gas separator sequentially connected to it in a downward direction. 4. Underground equipment according to claim 1, characterized in that a check valve is placed in the bottom of the hollow body open at the top. 5. Underground equipment according to claim 1, characterized in that the support sleeve has a conical seat, and the upper part of the hollow body open at the top — an annular outer protrusion with a conical lateral surface corresponding to the conical seat of the support sleeve, the lower part of the hollow body open at the top made in the form of a truncated cone. 6. Underground equipment according to claim 2, characterized in that the mechanism for compensating the axial movement of the submersible pump layout is made in the form of a concentrically spaced pipe having hydraulic communication with the external space and a rod forming a limited movable connection, and at one end of the pipe the inner annular protrusion, the other end is muffled, and the rod has an outer annular protrusion for interaction with the inner annular protrusion of the pipe in the extended position of the connection.

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