RU2817925C1 - Method and device for destruction of cement stone behind casing pipe - Google Patents

Abstract

FIELD: mining.

SUBSTANCE: group of inventions relates to construction of oil and gas wells and can be used for destruction of cement stone behind a casing string without its destruction, for subsequent extraction of the string. Method includes lowering into the well on tubing to the level of the destructible section of the spacer device, which includes adjustable jaws in the form of a part of the cylinder cut off by the plane, parallel to its longitudinal axis, flat surfaces facing each other, and hydraulic jack installed between them, filling of tubing with working fluid under pressure, providing activation of well spacer device, which creates a radial force on the casing of an oil or gas well in two diametrically opposite directions under the action of a jack perpendicular to the flat surfaces of the jaws in diametrically opposite directions with force specified within elastoplastic deformation of casing string without its destruction and with destruction of cement stone around casing pipe. Pressure is released in the tubing string, the spacer device is turned about its axis, and pressure is re-supplied to the tubing string. Further, the sequence of operations is repeated, the device is moved vertically along the well to the level of the undisturbed cement stone, the pressure of the working fluid in the tubing is increased and the cycle of operations is repeated. Outer part of the jaws corresponds to the inner part of the casing at the section of their contact and with the free surface of the tube between the jaws.

EFFECT: efficient destruction of cement stone, ruled out damage to casing pipe, reduced time of operations.

6 cl, 4 dwg

Description

Field of technology

The invention relates to the construction of oil and gas wells and can be used to destroy the cement stone behind the well casing without destroying it, for subsequent removal of the column from the well.

State of the art

There is a known method for removing casing pipes from wells (patent RU 2110662 C1), which consists of preliminary drilling and tensioning them using the traveling rig system, while drilling is carried out by drilling next to the casing string of a new well, destroying the soil around the pipe by at least by 1/4 the length of its circumference, in depth by the full length of the casing string, and the tension of the casing string is carried out at an angle to the well axis.

The disadvantage of this method is the large volume of drilling associated with the destruction of cement stone around the casing, as well as the need to ensure high accuracy of device positioning and the complexity of the operations performed.

The closest to the invention in technical essence and the result achieved by it is a method for extracting part of a production string (patent RU 2110662 C1), including lowering a cutting device, cutting out a section of the casing in the kickoff zone, while the casing in the kickoff zone is cut off, lifted, cemented, and a cement bridge is installed on the open part of the wellbore and a side trunk is drilled from it, and if there is cement stone in the annular space, the integrity of the cement stone between the conductor and the casing is first destroyed to a depth below the conductor shoe of at least 50 m using a special device - a drill with a fishing rod. left" tap or if there is cement stone in an area more than 50-100 m from the conductor shoe in the annular space between the conductor and the production casing, after work has been carried out to remove the casing and it is further impossible to remove the casing below the conductor shoe, a whipstock is installed and cutting is carried out " window" above the conductor shoe with a diameter greater than the diameter of the planned bit and sidetracking with the normal diameter of the drilling tool.

The disadvantage of this method is that in order to destroy the cement stone, it is necessary to provide direct access to it by violating the integrity of the casing.

A hydraulic power device is known (author's certificate SU 1530769), including a tube made of elastic material, end plugs with fittings for supplying the working fluid into the tube, punches with gable longitudinal bores on the internal surfaces covering the tube, inserts in the form of wedges in cross section, installed longitudinally between the punches, adjacent with inclined edges to the slopes of the punch bores and with large bases facing the tube, it is also equipped with bushings rigidly connected to the end caps, while transverse grooves are made on the outer surfaces of the ends of the punches, and the bushings are located to cover the radial clearance of the ends of the punches with grooves.

The closest to the device proposed in the invention in terms of technical essence and achieved result is a device (patent RU 2622275 C1), containing a detachable housing along its longitudinal axis with annular cavities at its ends, a mechanism for returning them to the non-working position installed on parts of the housing, located inside the split housing there is an elastic chamber, expansion inserts placed between parts of the split housing with guide grooves, protrusions of the expansion inserts installed with the ability to move along them, interacting with them and with the elastic chamber, end sealing clips with cylindrical flanges with a fitting for supplying the working agent to the elastic chamber and a fitting for displacing air from this chamber, a working agent volume limiter located between the fittings, having a body with a longitudinal slot, containing a bushing, interacting with it through a control element, a spring-loaded pusher in contact with the control element, and a thrust element interacting with it, wherein the control element is installed in the longitudinal slot of the body of the working agent volume limiter and is in contact with the inner wall of the elastic chamber, while one end of the body of the working agent volume limiter is connected to the working agent supply fitting via a pusher installed with the ability to move along the axial channels of the body and fitting and equipped with grooves for the passage of the working agent agent, and the opposite end of the limiter body is freely placed in the channel of the air outlet fitting and is in contact with the sleeve, while the latter and the adjacent end of the body have holes for the passage of the working agent, while the elastic chamber is made with longitudinal corrugations, and the distance between diametrically located points the corrugation in the plane of the expanding inserts is less than the distance between their similar points relative to the longitudinal axis of the body parts, and the control element, located in the plane of symmetry of the expanding inserts, is in contact with the inner surface of the longitudinal corrugations of maximum diameter, while the guide grooves and the protrusions of the expanding inserts installed in them have a semi-cylindrical shape.

The disadvantage of the known stone destruction devices is that they do not remain operational in wells filled with liquid, which creates high pressure from the outside on the device, which limits their scope of application. Moving the device along the well to an undamaged area is difficult, since there is no possibility of returning to its original state due to the external pressure of the well fluid. Also, known devices do not allow creating a pulse (shock) force on the stone, which reduces the efficiency of its operation.

Disclosure of the invention

The problem posed by the proposed invention is to destroy the cement stone of the well behind the casing while maintaining the integrity of the casing for its further extraction, as well as to reduce the time of operations.

The technical result is the creation of a downhole spacer device, which makes it possible to implement a method for destroying cement stone behind the casing pipe of an oil or gas well without damaging the casing pipe.

The technical result is achieved as follows.

The proposed method includes lowering a spacer device into the well on pump-compressor pipes (tubing) to the level of the destroyed section, filling the tubing with working fluid under pressure, ensuring that the downhole spacer device is activated, which creates a radial force on the well casing in two diametrically opposite directions, in this case, the force of the spacer device is set within the limits of elastoplastic deformation of the casing pipe, which ensures deformation of the casing pipe without its destruction, the pressure in the tubing is released, the device is rotated at a given angle and pressure is re-injected into the tubing, then the sequence of operations is repeated after destruction of the cement stone for With the casing pipe, the spacer device is moved vertically along the well to the level of unbroken cement stone, the pressure of the working fluid in the tubing is increased and the above-described sequence of operations is repeated.

A downhole spacer device includes adjustable cheeks and a hydraulic jack installed between them, with each of the adjustable cheeks made in the form of a part of a cylinder, cut off by a plane parallel to its longitudinal axis, the outer part of the cheeks corresponds to the inner part of the pipe in which the device will be used, the cheeks face each other with their flat surfaces, and the jack is installed so that its impact is directed perpendicular to the flat surfaces of the cheeks in diametrically opposite directions.

The proposed method ensures radial deformation of the casing pipe in two diametrically opposite directions using a spacer device from a circle to an ellipse without its destruction, while the forces transmitted through the casing pipe exceed the tensile strength of the cement stone located around the casing pipe.

By selecting the force on the spacer device within the elastoplastic deformation of the casing pipe, the integrity of the pipe is maintained and its geometric shape is only slightly changed.

A hydraulic jack is installed inside the device, which is designed in such a way that the force is created only in the direction of its opening, while eliminating additional losses due to housing deformation in other directions and increasing the efficiency of the device. The jack can be made in the form of a hydraulic sliding cylinder containing a housing and at least one sliding piston, or in the form of an elastic element compressed along the longitudinal axis, which restores its original shape when pressure is applied to the internal cavity. Making the outer surface of the cheeks in the form of a reciprocal inner surface of the casing pipe allows you to create a distributed load on the pipe section, which will avoid its destruction. The outer surface of the cheeks can be made in the form of a corresponding inner surface of the pipe only in the area of contact between the cheeks and the pipe, while leaving a free surface of the pipe between the cheeks.

The essence of the technical solution is illustrated by figures, where in Fig. 1 schematically shows a well and a spacer device lowered into it, and FIG. 2 – sectional spacer device; in fig. 3, 4 section along А-А for different versions of the spacer device.

Carrying out the invention

The proposed method is carried out, and the device operates as follows.

The spacer device 1 is lowered into the well 2 on tubing pipes 3 to the level of the extreme boundary 4 of the destroyed area, the pump and compressor pipes 3 are filled with working fluid under pressure H3 (Fig. 1), which ensures that the downhole spacer device 1 is put into operation. Under the action of the jack 5, the cheeks 6 move apart and create a radial force on the casing pipe 7 of the well in two diametrically opposite directions. Due to the fact that the internal flat surfaces of the cheeks 6 are made parallel to each other, and the jack 5 is installed so that its action is directed perpendicular to the flat surfaces of the cheeks, the force from the jack 5 is transmitted focused only in diametrically opposite directions, which increases the efficiency of the device 1. Downhole force The spacer device 1 is set within the elastic-plastic deformation of the casing pipe 7, therefore, under the influence of the force of the spacer device 1, the casing pipe 7 is deformed without its destruction. Thus, a slight deformation of the casing 7 occurs in diametrically opposite directions so that its cross section turns from a circle into an ellipse without being destroyed. In this case, in the cement stone 8 located around the casing, forces arise that exceed its strength limit (exceed the limit of elastic deformation of the cement stone), thereby destroying the cement stone 8 behind the casing pipe 7. Then the pressure in the tubing 3 is released. In this case, the well spacer device 1, under the influence of external pressure of the well fluid, returns to its original state and the jaws 6 move towards each other, which allows the well spacer device 1 to be rotated around its axis. Pressure is reapplied to tubing 3 and the cement stone behind the casing is destroyed. Then the pressure in the tubing 3 is released and the downhole spacer device 1 is moved vertically along the well to the level of unbroken cement stone. Then the cycle repeats.

Pulsing fluid into the tubing will create a shock load on the casing, which contributes to more efficient destruction of the cement stone.

A jack 6 is installed inside the downhole spacer device, which transmits the force created by the liquid located inside the tubing 3. The jack can be made in the form of a hydraulic cylinder or a flexible rubber deformable element that transmits its force along one axis, thereby significantly increasing the efficiency of the device and eliminating losses associated with deformation of the device body.

The spacer device is attached to the tubing through a thread located on the cover 8 in which channel 9 is located for supplying the working fluid. For ease of technological operations, the spacer device can be made up to 12 meters long, while several spacer devices can be combined into a vertical garland to increase the area of destruction of the cement stone.

Claims (6)

1. A method for destroying cement stone behind the casing pipe of an oil or gas well, including lowering into the well on tubing to the level of the destroyed section of a spacer device, including adjustable jaws in the form of a part of a cylinder, cut off by a plane parallel to its longitudinal axis, facing flat surfaces to each other, and a hydraulic jack installed between them, filling the tubing with working fluid under pressure, ensuring that the downhole spacer device is activated, which creates a radial force on the casing of an oil or gas well in two diametrically opposite directions when the jack acts perpendicular to the flat surfaces cheeks in diametrically opposite directions with a force specified within the elastoplastic deformation of the casing without its destruction and with the destruction of the cement stone around the casing, the pressure in the tubing is released, the spacer device is rotated around its axis, pressure is re-supplied into the tubing, then the sequence of operations repeat, move the device vertically along the well to the level of the unbroken cement stone, increase the pressure of the working fluid in the tubing and repeat the cycle of operations, with the outer part of the cheeks corresponding to the inner part of the casing in the area of their contact and with the free surface of the pipe between the cheeks. 2. The method according to claim 1, characterized in that the radial force on the casing is created along the opening plane of the spacer device. 3. The method according to claim 1 or 2, characterized in that the radial force on the casing is created by pulsed fluid supply into the tubing. 4. A downhole spacer device, including adjustable cheeks and a hydraulic jack installed between them, with each of the cheeks made in the form of a part of a cylinder, cut off by a plane parallel to its longitudinal axis, the cheeks face each other with flat surfaces, and the jack is installed with the possibility of impact, directed perpendicular to the flat surfaces of the cheeks in diametrically opposite directions. 5. The device according to claim 4, characterized in that the jack is made in the form of a hydraulic cylinder. 6. The device according to claim 4, characterized in that the jack is made in the form of a deformable elastic element that changes its shape when pressure is applied.