RU2292447C1 - Device for depression cleaning of well faces - Google Patents

Abstract

FIELD: oil and gas extractive industry, possible use for cleaning wells from slurry, sand, paraffin and other hard to extract sedimentations.

SUBSTANCE: device includes depression chamber with separating piston, hydrodynamic action device, hydraulically connected by means of connecting sleeve to slurry-receiving chamber, gate valve in lower section of slurry receiving chamber. Upper part of piston is equipped with sub having shelves on lower end. Sub is connected to tubing column, while its lower part is provided with windows and is built into depression chamber, relatively to which in transporting position separating piston is held by shear elements with possible limited axial-only downward movement. In transport position windows of piston are hermetically, by means of packing elements, are sealed by depression chamber. Upper end of depression chamber is provided with recesses, made with possible interaction with shelves of lower end of sub. Depression chamber is connected to hydrodynamic action device by means of sleeve. Hydrodynamic action device is made in form of differential valve, mounted in upper part of slurry-receiving chamber and spring-loaded relatively to depression chamber. Depression and slurry-receiving chambers are made with possible approach during rotation relatively to each other. Slurry-receiving chamber on outside is equipped downwardly with packing and holding mechanisms. Packing mechanism is made in form of upper stop with radial channels, elastic sleeve and conic lower stop, made with possible limited upward movement relatively to slurry-receiving chamber. Holding mechanism is made in form of bushing with spring localizers and dies spring-loaded towards inside, made with possible interaction with conic lower stop of packing mechanism. Lower end receiving section of slurry-receiving chamber is made in form of pipe spider and is screwed to slurry-receiving chamber by means of an adapter. Lower end receiving part is made with possible interaction with face without rotation and approach to slurry-receiving chamber during relative rotation relatively to one another. Slurry-receiving chamber is additionally provided with radials apertures closed in transport position by upper stop, which are made with possible combination with radial channels of upper stop. Upper stop of packing mechanism and bushing of holding mechanism are held in transport position relatively to slurry-receiving chamber by means of shear screws. Plug-valve is built in above separating piston, made in form of stripping valve.

EFFECT: increased reliability, lower costs.

2 dwg

Description

The invention relates to the oil and gas industry and can be used as processing equipment for cleaning the bottom (sump) of wells from sludge, sand, paraffin and other hard to remove deposits.

A device for cleaning the bottom of the well (copyright certificate SU No. 2099506, IPC 7 E 21 V 37/00, publ. Bull. No. 22, 1995), comprising a housing with a depression chamber and a dummy valve, a sludge collection chamber, a separation chamber piston, shock rod with shear pins, sliding piston lock.

The disadvantages of this device are:

- firstly, the low filling of the sludge receiving chamber with well cleaning products due to the influence of the pressure of the liquid column in the production casing, which reduces the efficiency of the device;

- secondly, the device does not provide protection of casing and a cement ring in annular space from deep water bumps at the moment of creating a depression in the cleaning zone in deep wells, as a result of which the wellbore is weakened when the cement ring breaks, which leads to complications, such as annular flow liquids and pollution of freshwater horizons.

The closest in technical essence to the proposed is a device for depressurization of bottom hole treatment (patent RU No. 2213847, IPC 7 E 21 B 37/00, publ. Bull. No. 28 from 2003), including a depression chamber with a separation piston, hydraulically connected to sludge-receiving chamber, and means of overlap, made in the form of a shutter valve, located in its lower part, while it is equipped with a hydrodynamic impact device made in the form of a diffuser-confuser and an elastic ball mounted between the dividing piston, in A differential and sludge-receiving chamber with an end receiving part made in the form of a pipe spider, while above the dividing piston, additionally has a built-in valve plug for communicating the internal cavity of the tubing with the annular space of the well when removing the device to the surface.

The disadvantages of this device are:

- firstly, before lifting the device to the surface, it does not ensure removal of cleaning products from the bottom of the depression and sludge receiving chambers from the bottom of the well, which creates additional loads on the lifting unit, leading to a decrease in the lifting speed of the device, and also increases the likelihood of failure of one or several elements of equipment layout at once. In addition, the diaphragm of the valve plug, which collapses under the action of excessive pressure, requires high precision manufacturing, failure to observe which leads to the destruction of the valve plug before reaching the set pressure value. In addition, with a large depression on the formation, sticking of the elastic ball in the passage channel of the hydrodynamic impact device is possible. All of the above factors reduce the reliability of the device for cleaning the bottom of the well;

- secondly, as the device is cured to the surface and the cleaning products removed from the depression and sludge receiving chambers from the bottom, the wellhead is contaminated, which leads to a violation of environmental requirements;

- thirdly, the complexity of the control of technological operations during depressurization cleaning of the bottom of the well, in addition, the reservoir is not protected from the products of treatment, and shock is possible at the time of the creation of depression in the zone of purification of the bottom of the well, accompanied by a sharp jump in pressure, which can lead to a violation of the integrity support the well and reservoir and the deterioration of the reservoir properties of the latter.

The objective of the invention is to increase the reliability of the device by washing the cleaning products before lifting the device to the surface with the ability to control ongoing technological operations, increasing environmental friendliness, as well as maintaining the reservoir properties of the formation by eliminating the ingress of cleaning products from the bottom of the well.

The problem is solved by the proposed device for the depressurization of wells, including a depression chamber with a separation piston, hydraulically connected to the sludge receiving chamber through a hydrodynamic impact device, a shutter valve located in the lower part of the sludge receiving chamber, the lower end receiving part of which is made in the form of a pipe spider, this above the separation piston, in addition, a plug valve for communicating the inner cavity of the tubing with an annular space when removing the device to the surface.

What is new is that the upper part of the separation piston is equipped with an adapter with protrusions at the lower end connected to the tubing string, and the lower part is installed in a depression chamber, relative to which it is fixed in the transport position by shear elements with the possibility of limited movement downward, while the upper the end face of the depression chamber is equipped with depressions made with the possibility of interaction with the protrusions of the lower end of the sub, and the device of hydrodynamic effects made in the form of a differential valve mounted in the upper part of the sludge receiving chamber and spring-loaded relative to the depression chamber, while the depression chamber and sludge receiving chamber are adapted to approach when rotating relative to each other, the sludge receiving chamber is equipped from the outside with top-down packing and fixing mechanisms, and the packing mechanism is made in the form of an upper stop with radial channels, an elastic cuff and a conical lower stop, made with the possibility of limited pe upward movement relative to the sludge receiving chamber, and the fixing mechanism is made in the form of a sleeve with spring centralizers and dies spring-loaded inside, made with the possibility of interaction with the conical lower stop of the packing mechanism, while the lower end receiving part is configured to interact with the face without rotation and approaching the sludge receiving the camera when rotating relative to each other, moreover, the sludge collection chamber is additionally equipped with a top stop openings that are compatible with the radial channels of the upper stop, while the upper stop of the packing mechanism and the sleeve of the locking mechanism are fixed in the transport position relative to the sludge receiving chamber with shear, upper and lower screws, respectively, and the valve plug is made in the form of a knockdown valve.

Figure 1 shows the upper part of the device depressive cleaning of the bottom of the wells in longitudinal section.

Figure 2 shows the lower part of the device depressive cleaning of the bottom of the wells in longitudinal section.

The device consists of a depression chamber 1 (see Fig. 1) with a separation piston 2, a hydrodynamic impact device 3, hydraulically connected by means of a coupling 4 with a sludge receiving chamber 5, a shutter valve 6 located in the lower part of the sludge receiving chamber 5.

The upper part of the separation piston 2 is equipped with a sub 7 with protrusions 8 at the lower end. The sub 7 is connected to the tubing string 9, and the lower part is equipped with windows 10 and installed in the depression chamber 1, relative to which in the transport position the separation piston 2 is fixed by shear elements 11 with the possibility of limited axial movement downward. In addition, in the transport position, the windows 10 of the separation piston 2 are sealed, by means of the sealing elements 12, are closed by the depression chamber 1.

The upper end of the depression chamber 1 is equipped with depressions 13, made with the possibility of interaction with the protrusions 8 of the lower end of the sub 7.

The depression chamber 1 is connected to a hydrodynamic device 3 using a coupling 14.

The hydrodynamic impact device 3 is made in the form of a differential valve mounted in the upper part of the sludge receiving chamber 5 and spring-loaded relative to the depression chamber 1 by means of a spring 15.

Depression 1 and sludge receiving 5 chambers are made with the possibility of rapprochement during rotation relative to each other. The sludge receiving chamber 5 is outside equipped with top-down packer 16 (see FIG. 2) and locking mechanisms 17.

The packing mechanism 16 is made in the form of an upper stop 18 with radial channels 19, an elastic cuff 20 and a conical lower stop 21 made with the possibility of limited upward movement relative to the sludge receiving chamber 5. The locking mechanism 17 is made in the form of a sleeve 22 with spring centralizers 23 and dies spring-loaded inside. 24, configured to interact with the conical lower stop 21 of the packing mechanism 16.

The lower end receiving part 25 of the sludge receiving chamber 5 is made in the form of a pipe spider and is screwed to the latter by means of an adapter 26.

The lower end receiving part 25 is configured to interact with the face 27 without rotation and approaching the sludge receiving chamber 5 with relative rotation relative to each other.

The sludge collection chamber 5 is additionally equipped with radial holes 28 that are overlapped in the transport position by the upper stop 18, which are adapted to be aligned with the radial channels 19 of the upper stop 18.

The upper stop 18 of the packing mechanism 16 and the sleeve 22 of the locking mechanism 17 are fixed in the transport position relative to the sludge receiving chamber 5 with shear screws 29 and 30 lower respectively.

Above the separating piston 2 (see FIG. 1), an additional plug valve 31 is built in the form of a knockout valve for communicating the internal cavity of the tubing 9 with the annulus when the device is removed to the surface.

Device depressive cleaning of the bottom of the wells works as follows.

The device by means of a sub 7 (see Fig. 1) is connected to the tubing string 9 and assembled (see Figs. 1 and 2) is lowered into the well until it stops at the bottom 27, after which, by unloading the tubing string 9 to the bottom, an axial load is created down 30-40 kN, the shear element 11 is destroyed, and the separation piston 2, rigidly connected from above with the sub 7 (see Fig. 1), is shifted down, while the sub 7 with its depressions 8 comes into contact with the depressions 13 with which the upper end of the depression chamber 1 with the possibility of subsequent rotation. After that, the tubing string 9 with the device is completely unloaded to the face 27 (see figure 2). This is visually monitored at the wellhead by a change in the weight indicator (not shown), while the weight indicator readings fall and the tubing string 9 is moved downward, as a result of which the depression 2 and sludge receiving 5 chambers are communicated through a hydrodynamic device 3.

Under the action of a pressure drop above and below the separation piston 2, an implosion effect occurs in the depression chamber 1, and absorption begins through the lower end receiving part 25, made in the form of a pipe spider (see Figs. 1 and 2), into the sludge receiving chamber 5 of deposits (sludge , sand) from the bottomhole 27 of the well, while the shutter valve 6 opens and deposits from the bottomhole 27 fill the sludge receiving chamber 5 (see Fig. 2).

The hydrodynamic action device 3 (see FIG. 1) located between the separation piston 2 and the sludge receiving chamber 5 is spring-loaded by means of a spring 15 relative to the depression chamber 1 and, under the action of the created differential pressure, creates an adjustable effect. The pressure difference changes the flow area of the device hydrodynamic effects 3 and contribute to the additional removal of deposits from the bottom 27 and eliminates water hammer. The greater the pressure drop between the depression 1 and the sludge receiving 5 chambers, the more the hydrodynamic impact device 3 is drawn in, compressing the spring 15, and the smaller its passage section.

At the end of the depressurization treatment, the pressures in the depression chamber 1 and sludge receiving chamber 5 equalize, and the depressurization time from deposits from the bottom 27 (see figure 2) is determined empirically and depends on the depth of the device and the degree of contamination of the bottom of the well.

Then the device is lifted from the bottom by 3-5 meters, while the shutoff valve 6 closes, excluding the reverse loss of deposits in the sludge receiving chamber 5, to the bottom 27. The presence of borehole fluid and sediment products in the sludge receiving chamber 5 indicates an excess of readings weight indicator over the original, that is, the weight of the device with the tubing string 9 before unloading at the bottom 27.

The device is again completely unloaded to the bottom of the well, after which they begin to rotate the tubing string 9 from the wellhead (Figs. 1 and 2) not clockwise, while the tubing string 9 (see Fig. 1) transmits torque to the upper part devices due to the hard contact of the depressions 8 and 13, respectively, of the adapter 7 and the depression chamber 1, as a result of which the tubing string 9 and the upper part of the device, including the sleeve 14, rotate and, along the external thread 32 of the hydrodynamic impact device 3, lower down, compressing the spring 15. Rotation the columns The tubing 8 is continued until the external thread 32 ends, as a result of the passage channel of the hydrodynamic impact device 3, it fully opens and maintains the passage section.

The rotation of the tubing string 9 from the wellhead continues clockwise, as a result of which the tubing string 9 together with the device, with the exception of the locking mechanism 17 (see FIG. 2) and the lower end receiving part 25 of the sludge receiving chamber 5 with adapter 26, rotate and the external thread 33 of the sludge receiving chamber 5 is lowered downward, and the lower screw 30, which fixes the sleeve 22 in the transport position relative to the sludge receiving chamber 5, is destroyed. The rotation of the tubing string 9 continues until the end of the external thread 33.

Then the tubing string 9 with the device is lifted up so that the packer 16 is located above the reservoir in the well (not shown).

Further, the tubing string 9 with the device begins to be lowered downward, while the fixing device 17, due to the contact of the spring centralizers 23 with the wall 34 of the well, remains stationary, and at some point, the springs 24 of the fixing mechanism 16 spring-loaded interact with the conical lower stop 21 of the packing mechanism 16. With the further lowering of the device, the upper screw 29, which fixes the upper stop 18 in the transport position relative to the sludge receiving chamber 5, is destroyed. the top of the packing mechanism 16 before interacting with the upper stop 18 in the lower end of the connecting sleeve 35 of the sludge receiving chamber 5. At this point, the radial channels 19 of the upper stop 18 and the radial holes 28 of the sludge receiving chamber 5 are combined. The device continues to be lowered, while the dies spring-loaded inside are fixed 24 of the fixing mechanism 16 on the walls 34 of the well, and upon subsequent downward movement of the device, it is unloaded onto the aforementioned spring-loaded rams 24, while the elastic cuff 20 is compressed and pressed against the walls 34 of the well, hermetically cutting off part of it located below the device, including the formation.

Direct or reverse washing removes sediment products from the device from the bottom of the well located in it after the depressurization, while the preliminary flow line of the well is connected to a barn or trough (not shown in Figs. 1 and 2) in order to comply with environmental requirements.

At the end of the flushing, before the device begins to rise to the surface, a well (not shown) is discharged into the wellhead string 9, which destroys the plug valve 31, made in the form of a knock-off valve (see Fig. 1), as a result of which the depression chamber 1 and the inner space of the tubing 9 with the annulus of the well, preventing overflow of the wellbore fluid at the mouth when lifting the device to the surface. The destruction of the valve plug 31 is indicated by the weight loss of the well fluid during the lifting of the device, which is displayed on the weight indicator.

The proposed device meets environmental requirements and is reliable in operation due to washing out the cleaning products before lifting the device to the surface, while the full control of technological operations is possible, and the reservoir properties are maintained due to the use of a packing device that prevents deposits from entering the formation from the bottom of the well and eliminates work to restore reservoir productivity, and, as a result, avoids additional material and financial costs al.

Claims (1)

A device for depressurizing the bottom of the well, including a depression chamber with a separation piston, hydraulically connected to the sludge receiving chamber through a hydrodynamic impact device, a shutter valve located in the lower part of the sludge receiving chamber, the lower end receiving part of which is made in the form of a pipe spider, while above the separating piston Additionally, a plug valve is installed to communicate the internal cavity of the tubing with the annulus when removing the device rhine, characterized in that the upper part of the separation piston is equipped with a sub with protrusions on the lower end connected to the tubing string, and the lower part is installed in the depression chamber, relative to which in the transport position it is fixed by shear elements with the possibility of limited movement down, while the upper end of the depression chamber is equipped with troughs configured to interact with the protrusions of the lower end of the sub, and the device is hydrodynamic air The action is made in the form of a differential valve mounted in the upper part of the sludge receiving chamber and spring-loaded relative to the depression chamber, while the depression chamber and sludge collection chamber are made to approach each other when rotating relative to each other, the sludge collection chamber is equipped from the outside with top-down packing and fixing mechanisms, and the packing mechanism made in the form of an upper stop with radial channels, an elastic cuff and a conical lower stop, made with the possibility of limiting movement upward relative to the sludge receiving chamber, and the locking mechanism is made in the form of a sleeve with spring centralizers and dies spring-loaded inside, made with the possibility of interaction with the conical lower stop of the packer mechanism, while the lower end receiving part is configured to interact with the face without rotation and rapprochement with sludge-receiving chamber when rotating relative to each other, moreover, the sludge-receiving chamber is additionally equipped with an upper stop ohm radial holes, which are adapted to align with the radial channels of the upper abutment, the upper abutment packer mechanism and sleeve the locking mechanism fixed in the transport position relative shlamopriemnoy shear chamber, respectively upper and lower screws and the valve plug is formed as a whipped filling valve.

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