The present invention relates to the field of marine deepwater drilling technologies, and in particular, to a casing hanger and annulus sealing device running tool for deepwater drilling and a method for using the same.
Marine oil and gas resources have become an important source of energy supply. High output, high investment and high risk are the characteristics of exploration and development operations of marine deepwater oil and gas. The subsea wellhead system is a basic component of deepwater drilling, well completion, and oil extraction and other operations. A multilayer casing hanger and annulus sealing device are installed inside the subsea wellhead, where the casing hanger is used to suspend a casing, and apply the weight of the casing string to the subsea wellhead, and the sealing device is used to seal an annulus space between the casing hanger and the subsea wellhead to isolate an external annulus space of the casing above and below the casing hanger. The casing hanger, the annulus sealing device and a running tool of them run to the subsea wellhead together. How to install the casing hanger and the sealing device is the key to lower the casing and continue drilling. A reasonable design of the running tool can reduce construction steps and installation difficulty, and improve the reliability of installation operation.
In the prior art, there is existed a casing hanger and a sealing running tool for marine deepwater drilling, the tool needs to throw blocking darts and other instruments when lowering the piston and installing the casing annulus sealing device under the hydraulic assistance, and needs to install corresponding equipments on the derrick, increasing wellhead operation steps.
Therefore, based on years of experience and practice in related industries, the inventor proposes a casing hanger and annulus sealing device running tool for deepwater drilling and a method of using the same, to overcome the defects of the prior art.
An object of the present invention is to provide a casing hanger and annulus sealing device running tool for deepwater drilling and a method for using the same, to overcome the problems of complex installation, multiple matching equipment, high cost and so on in the prior art. The casing hanger and annulus sealing device running tool for deepwater drilling and the method for using thereof can achieve the requirements of installing a casing hanger and an annulus sealing device at a subsea wellhead on the seafloor, and have advantages of few installation and construction steps and low cost.
The object of the present invention is achieved as follows: a casing hanger and annulus sealing device running tool for deepwater drilling includes a hollow spindle, and an upper part of an outer wall of the spindle is hermetically connected to a hollow suspension structure via a hollow torque transmission structure, one end of the spindle away from the torque transmission structure slidably passes through a piston, an outer wall of the piston is connected to a lower part of an inner wall of the suspension structure in a sealed manner, an inner cavity of the suspension structure communicates with an inner cavity of the torque transmission structure to form a piston cavity, one end of the piston away from the torque transmission structure is located outside the piston cavity, the piston cavity and the piston form a hydraulic piston structure; a communication valve structure is provided between an inner wall of the torque transmission structure and the outer wall of the spindle, and the communication valve structure can communicate the piston cavity and an inner cavity of the spindle; the suspension structure includes a suspension cylinder capable of rotating with the spindle around a central axis, a bottom of an outer wall of the suspension cylinder is provided with an elastic pin capable of rotating to hook to and rotating to release an annulus sealing device, the elastic pin is capable of radially expansion and contraction; a lower part of an inner wall of the suspension cylinder is fixedly connected to a rotating cylinder in a sealed manner, the rotating cylinder can rotate with the suspension cylinder, an inner wall of the rotating cylinder is connected to the outer wall of the piston via a thread, and the piston and the rotating cylinder form a lead screw nut structure; one end of the piston away from the torque transmission structure is sleeved with an open type lock ring and the open type lock ring can open radically to hook to a casing hanger and contract radically to release the casing hanger.
In a preferred embodiment of the present invention, a bottom of the spindle is sleeved with a hollow lower joint, and a top of an outer wall of the lower joint can seal against an inner wall of the piston.
In a preferred embodiment of the present invention, a spindle through-hole that allows the spindle to slide therethrough in a sealed manner is provided inside the piston. A first diameter-enlarged hole with an enlarged inner diameter is provided below the spindle through-hole. A second diameter-enlarged hole is provided inward at one end of the piston away from the torque transmission structure. The first diameter-enlarged hole communicates with the second diameter-enlarged hole through a first tapered surface that has an inner diameter gradually increasing from top to bottom. The top of the outer wall of the lower joint can slide against an inner wall of the first diameter-enlarged hole in a sealed manner. The outer wall of the lower joint is provided with a first boss part, an outer wall of the first boss part slide against an inner wall of the second diameter-enlarged hole in a sealed manner. A top of the first boss part is provided with a second tapered surface capable of abutting against the first tapered surface in a sealed manner.
In a preferred embodiment of the present invention, the torque transmission structure includes a hollow connecting disc body that is sleeved on the spindle in a sealed manner. The communication valve structure is provided between an upper part of an inner wall of the connecting disc body and the outer wall of the spindle. The torque transmission structure further includes a hollow driving cylinder capable of moving axially along the spindle, a top of the driving cylinder can slide provided in an inner cavity of the connecting disc body in a sealed manner. The communication valve structure is in communication with the piston cavity, one end of the suspension cylinder is provided in an inner cavity of the driving cylinder, and the connecting disc body is fixedly connected with the suspension cylinder via a torque transmission bar. Outsides of the connecting disc body and the driving cylinder are provided with a centralizer structure.
In a preferred embodiment of the present invention, the centralizer structure includes an outer cylinder disposed coaxially with the driving cylinder; a top of the outer cylinder is fixedly connected to the connecting disc body. A lower part of a side wall of the outer cylinder is connected to a lower part of a side wall of the driving cylinder via a shear pin.
In a preferred embodiment of the present invention, the connecting disc body is connected with the spindle by a plurality of first connection pins; an upper part of a side wall of the connecting disc body is provided with a plurality of first through-holes. A side wall of the spindle is provided with first connection holes at positions corresponding to the first through-holes, and the first connection pins are connected to the inside of the first connection holes after passing through the first through-holes.
In a preferred embodiment of the present invention, an outer wall of the connecting disc body is sleeved with a first snap ring, and a bottom surface of the first snap ring abuts against a top surface of the torque transmission bar.
In a preferred embodiment of the present invention, the communication valve structure includes a valve body that abuts and is sleeved between the outer wall of the spindle and the inner wall of the connecting disc body. The outer wall of the spindle is provided with a first step part, the inner wall of the connecting disc body is provided with a second step part with a reduced diameter; one end surface of the valve body abuts against the first step part, and the other end surface of the valve body abuts against the second step part. A valve core hole through up and down is provided inside the valve body, a valve core is slidably provided inside the valve core hole. One end of the valve core is sleeved with a valve core spring. One end of the valve core spring abuts against the first step part, and the other end of the valve core passing through the valve body is located in the inner cavity of the driving cylinder. A valve core hole tapered surface with a diameter gradually decreasing from top to bottom is provided inside the valve core hole. The outer wall of the valve core is provided with a valve core tapered surface capable of matching with and sealing against the valve core hole tapered surface. The side wall of the spindle is provided with a first communication through-hole. A valve body communication hole that is in communication with the first communication through-hole is provided on a side wall of the valve core hole. One end of the valve core is inwardly provided with a first passage hole capable of communicating with the valve core hole and the valve body communication hole, the other end of the valve core is inwardly provided with a second passage hole capable of communicating with the piston cavity and the valve body communication hole. A bottom open of the first passage hole is located above the valve core tapered surface, and a top open of the second passage hole is located below the valve core tapered surface.
In a preferred embodiment of the present invention, a plurality of elastic lock blocks capable of radially expansion and contraction are provided on a side wall of the rotating cylinder at intervals along a circumferential direction, and a plurality of key grooves are provided on the inner wall of the suspension cylinder. The elastic lock blocks can protrude radially and radial outer sides of the elastic lock blocks can be respectively locked into corresponding key grooves. The outer wall of the piston above the key grooves is provided with piston grooves. The elastic lock blocks can radially contract and radial inner sides of the elastic lock blocks can slide in the piston grooves.
In a preferred embodiment of the present invention, one end of the rotating cylinder located outside the suspension cylinder can rotate to be sleeved on a top of an outer wall of a tapered sleeve, and the tapered sleeve has an outer diameter that is tapering from top to bottom. The rotating cylinder can push the tapered sleeve to move downward so as to open the open type lock ring.
In a preferred embodiment of the present invention, the tapered sleeve is provided with at least one tapered sleeve open type through slot with a bottom open, along an axial direction. The outer wall of the piston is fixedly provided with an anti-torsion key corresponding to the tapered sleeve open type through slot. The tapered sleeve open type through slot is slidably sleeved on circumferential two sides of the anti-torsion key.
The object of the present invention can also be achieved in the following way. A method for using the casing hanger and annulus sealing device running tool for deepwater drilling described above includes the following steps:
Step a: after the casing hanger and annulus sealing device running tool for deepwater drilling is connected with the annulus sealing device and the casing hanger, lift up the drill pipe, remove a slip, lower the drill pipe, to send the casing hanger and annulus sealing device running tool for deepwater drilling, the annulus sealing device, the casing hanger and the casing to a subsea wellhead;
Step b: pump cement into the drill pipe to start cementing;
Step c: lower the drill pipe, lock the casing hanger onto a step surface of the subsea wellhead, and mark a circumferential position and a vertical position of the drill pipe on a derrick;
Step d: rotate the drill pipe clockwise, the drill pipe then drives the spindle, the valve body, the connecting disc body, the torque transmission bar, the driving cylinder, the suspension cylinder and the rotating cylinder to rotate, the rotating cylinder drives the tapered sleeve to move upward, and when a bottom end surface of the tapered sleeve is parallel to a top end surface of the open type lock ring, the open type lock ring is contracted radially, and thereby the casing hanger and annulus sealing device running tool for deepwater drilling is released from the casing hanger;
Step e: continue to rotate the drill pipe clockwise for a predetermined number of turns, to allow the rotating cylinder to rotate and rise until the elastic lock blocks leave the key grooves, and when the rotating cylinder rotates and rises until the elastic lock blocks reach positions where the piston grooves are located, the elastic lock blocks are contracted radially, and their radial inner ends slide into the piston grooves, then the rotating cylinder separates from the suspension cylinder, and the rotating cylinder stops rotating;
Step f: lower the drill pipe, the drill pipe drives the connecting disc body, the torque transmission bar, the driving cylinder, the suspension cylinder, and the annulus sealing device to descend, the annulus sealing device is then sleeved on an outer wall of the casing hanger, and the second boss part on a top of the piston passes into the through-hole of the driving cylinder, the driving cylinder and the piston form a piston sealing structure, forming a hydraulic auxiliary piston;
Step g: drill pipe drives the spindle, the connecting disc body, the torque transmission bar, the driving cylinder, and the suspension cylinder to continue to descend, a volume of the piston cavity decreases, and a pressure in the piston cavity increases, the valve core moves upward, the second passage hole communicates with the inner cavity of the spindle through the valve body communication hole and the first communication through-hole, the piston cavity communicates with the inner cavity of the spindle, and the fluid in the piston cavity flows into the inner cavity of the spindle; the drill pipe continues to descend and when a displacement of the drill pipe in a vertical direction reaches a predetermined displacement, the top end surface of the second boss part pushes the valve core upward; the piston cavity communicates with the inner cavity of the spindle 1 via the second passage hole, the valve body communication hole and the first communication through-hole;
Step h: operate a hydraulic equipment at a derrick to pressurize the interior of the drill pipe, a high-pressure fluid enters the piston cavity through the first communication through-hole and the valve body communication hole, and the driving cylinder shears off the shear pin and continues to descend under the drive of the high-pressure fluid;
Step i: a bottom end surface of the driving cylinder transmits the hydraulic pressure to the annulus sealing device, the annulus sealing device seals the annulus space between the subsea wellhead and the casing hanger to insulate the annular pressure;
Step j: stop pressurizing, apply an axial tension to the drill pipe, to drive the spindle, the connecting disc body, the torque transmission bar, and the suspension cylinder to move upward, and the elastic pins are cut off under the action of the axial tension, the casing hanger and annulus sealing device running tool for deepwater drilling is released from the annulus sealing device; and
Step k: pull the drill pipe upward, to raise the casing hanger and annulus sealing device running tool for deepwater drilling out of the subsea wellhead and to the derrick, completing installations of the casing hanger and the annulus sealing device.
As described above, the casing hanger and annulus sealing device running tool for deepwater drilling provided by the present invention and the method for using the same include the following beneficial effects:
the casing hanger and annulus sealing device running tool for deepwater drilling of the present invention can realize the requirements of installing the casing hanger and the annulus sealing device at the subsea wellhead on the seafloor, and fully use the torque transmission structure, the suspension structure, the hydraulic piston structure and the lead screw nut structure in combination, where the suspension cylinder can rotate to hook to and rotate to release the annulus sealing device, the bottom of the piston can hook to and release the casing hanger, the hydraulic piston structure can apply driving force to the annulus sealing device, and the sealing and releasing of the annulus sealing device and the casing hanger can be achieved by a method of rotating the drill pipe. The casing hanger and annulus sealing device running tool for deepwater drilling of the present invention have less difficulty in operation, and the method for using the same has simple implementation steps, high installation reliability, and low cost, which is conducive to popularization and use.
In order to have a clearer understanding of the technical features, objects, and effects of the present invention, specific embodiments of the present invention will now be described with reference to the accompanying drawings.
As shown in
The casing hanger and annulus sealing device running tool for deepwater drilling of the present invention can realize the requirements of installations of the casing hanger and the annulus sealing device at the subsea wellhead on the seafloor, and fully use the torque transmission structure, the suspension structure and the hydraulic piston structure and the lead screw nut structure in combination, where the suspension cylinder can rotate to hook to and rotate to release the annulus sealing device, the bottom of the piston can hook to and release the casing hanger, the hydraulic piston structure can apply a driving force to the annulus sealing device, and the sealing and releasing between the annulus sealing device and the casing hanger can be realized by a method of rotating the drill pipe. The casing hanger and annulus sealing device running tool for deepwater drilling of the present invention has less difficulty in operation, simple implementation steps, high installation reliability, and low cost, which is conducive to popularization and use.
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The casing hanger and annulus sealing device running tool for deepwater drilling 100 of the present invention is assembled in the following manner:
seal rings are sleeved at required positions on the outer wall of the spindle 1, and the first positioning pins 121 are mounted on the first step part 2; the valve core 52 is mounted into the valve core hole 511 of the valve body 51 so that the bottom open of the first passage hole 521 correspondingly communicates with the valve body communication hole 512, and the valve core spring 53 is sleeved on the valve core convex column part; the valve body 51 is sleeved from the bottom of the spindle 1, the first positioning pins 121 are latched respectively in corresponding locking holes of the valve body 51, the upper end surface of the valve body 51 tightly abuts against the first step part 12 in the circumferential direction, and the valve core spring 53 pushes the valve core tapered surface to seal against the valve core hole tapered surface, the first passage hole 521 communicates with the inner cavity of the spindle 1 through the valve body communication hole 512 and the first communication through-hole 13, the valve core tapered surface and the valve core hole tapered surface form a tapered surface sealing that blocks the piston cavity 40 from the inner cavity of the spindle 1, and the valve body snap ring 14 is sleeved from the bottom of the spindle 1;
the connecting disc body 21 is sleeved from the bottom of the spindle 1, and the second step part 212 inside the connecting disc body 21 axially abuts against the lower end surface of the valve body 51, so that the first through-holes 213 on the side wall of the connecting disc body 21 are opposite to the first connection holes 15, the first connection pins 26 pass through the first through-holes 213 and then are connected into the first connection holes 15; the outer cylinder 24 is sleeved from the bottom of the connecting disc body 21 and is connected via a screw or a thread; the driving cylinder 22 is sleeved from the bottom of the spindle 1, and the third boss part 221 is set in the inner cavity of the connecting disc body 21 below the communication valve structure 5, and the third step part axially abuts against the bottom end surface of the connecting disc body 21, the driving cylinder 22 is rotated so that the pin fixing hole on the side wall thereof is opposite to the pin through-hole on the side wall of the outer cylinder 24, the shear pin 25 is fixed into the pin fixing hole via the pin through-hole; the suspension cylinder 31 is sleeved into the driving cylinder 22 from the bottom of the spindle 1 and the suspension cylinder 31 is rotated so that the connection threaded holes are opposite to the first torque transmission bar through-hole of connecting disc body 21 and the second torque transmission bar through-hole of the driving cylinder 22, the torque transmission bar 23 passes through the first torque transmission bar through-hole and the second torque transmission bar through-hole and then is fixedly connected to the connection threaded holes;
the open type lock ring 42 is sleeved from the top of the piston 41, and the bottom end surface of the open type lock ring 42 axially abuts against the top surface of the piston boss part 415, and the anti-torsion keys 341 is fixed onto the outer wall of the piston 41; the rotating cylinder 33 is rotatably sleeved on the outer wall of the piston 41 from the top of the piston 41, and the rotating cylinder 33 is rotated counterclockwise (left-rotating, the direction of rotation can be adjusted according to actual needs) to move downward, so that the two-halves type tapered sleeve 34 rotates to be locked to the bottom of the rotating cylinder 33, the rotating cylinder 33 continues to be rotated to push the tapered sleeve 34 to move downward to the top of the open type lock ring 42, the tapered sleeve 34 is rotated so that the tapered sleeve open type through slot 343 is aligned with the anti-torsion keys 341, respectively, and the rotating cylinder 33 continues to be rotated counterclockwise to move downward, and the tapered sleeve open type through slots 343 are respectively slidably sleeved on circumferential two sides of the anti-torsion keys 341;
the elastic lock blocks 331 are installed on the side wall of the rotating cylinder 33, the piston 41, the rotating cylinder 33 and the tapered sleeve 34, which are as a whole, are sleeved from the bottom of the spindle 1, and the rotating cylinder 33 is rotated clockwise (right-rotating), so that the radial outer side of the elastic lock blocks 331 stretch out radially and be locked in the corresponding key grooves 311 of the suspension cylinder 31, completing the fixed connection between the rotating cylinder 33 and the suspension cylinder 31; the lower joint 11 is hermetically connected to the spindle 1 via a thread, and the elastic pins 32 are installed at the bottom of the outer wall of the suspension cylinder 31, and then, as shown in
When the casing hanger and annulus sealing device running tool for deepwater drilling 100 of the present invention needs to be used to lower the casing hanger 92, the casing 93, the annulus sealing device 91 and the cement injection tool into the well, as shown in
The drill pipe 90 is lifted up, and the casing hanger and annulus sealing device running tool for deepwater drilling 100 and the annulus sealing device 91 are moved to a derrick (prior art). The casing hanger 92 and the casing 93, which are connected together, are placed on the derrick. The drill pipe 90 is lowered, and when the piston outer tapered surface at the bottom of the outer wall of the piston 41 and the casing hanger inner tapered surface of the inner wall of the casing hanger 92 are sealed against each other, the lowering is stopped.
The drill pipe 90 is rotated counterclockwise (left-rotating) to drive the spindle 1, the connecting disc body 21, the torque transmission bar 23, the driving cylinder 22, the suspension cylinder 31, the elastic lock blocks 331 and the rotating cylinder 33 to rotate. Under the action of the lead screw nut structure formed by the rotating cylinder 33 and the piston 41, the rotating cylinder 33 pushes the tapered sleeve 34 to move downward, the open type lock ring 42 moves outward and spreads in the radial direction, and is locked into the casing hanger annulus groove of the casing hanger 92. When the bottom end surface of the tapered sleeve 34 abuts axially against the top surface of the piston boss part 415, the rotation of the drill pipe 90 is stopped, and the connection between the casing hanger and annulus sealing device running tool for deepwater drilling 100 and the casing hanger 92 are completed.
The method for lowering the annulus sealing device 91 and the casing hanger 92 using the casing hanger and annulus sealing device running tool for deepwater drilling 100 is as follows:
Step a: after the casing hanger and annulus sealing device running tool for deepwater drilling 100 is connected with the annulus sealing device 91 and the casing hanger 92, lift up the drill pipe 90, remove a slip (prior art), lower the drill pipe 90, to send the casing hanger and annulus sealing device running tool for deepwater drilling 100, the annulus sealing device 91, the casing hanger 92, and the casing 93 to subsea wellhead;
Step b: pump cement into the drill pipe 90 to start cementing;
Step c: lower the drill pipe 90, lock the casing hanger 92 onto the step surface of the subsea wellhead 95 (prior art), and mark a circumferential position and a vertical position of the drill pipe 90 on a derrick (that is, mark the height and the circumferential angle of the drill pipe 90 above a turntable of the derrick; prior art);
Step d: rotate (right-rotate) the drill pipe 90 clockwise, drill pipe 90 drives the spindle 1, the valve body 51, the connecting disc body 21, the torque transmission bar 23, the driving cylinder 22, the suspension cylinder 31 and the rotating cylinder 33 to rotate, the rotating cylinder 33 drives the tapered sleeve 34 to move upward, and when a bottom end surface of the tapered sleeve 34 is parallel to a top end surface of the open type lock ring 42, the open type lock ring 42 contracts radially due to its own elastic force, and the casing hanger and annulus sealing device running tool for deepwater drilling 100 releases from the casing hanger 92, and the state is shown in
Step e: continue to rotate (right-rotate) the drill pipe 90 clockwise for a predetermined number of turns (determined by an actual situation), to allow the rotating cylinder 33 to rotate and rise to a certain height, so that the elastic lock blocks 331 leave the key grooves, and when the rotating cylinder 33 rises until the elastic lock blocks reach positions where the piston grooves are located, the elastic lock blocks 331 contract radially and their radial inner sides slide into the piston grooves 416, then the rotating cylinder 33 separates from the suspension cylinder 31, and the rotating cylinder 33 stops rotating;
Step f: lower the drill pipe 90, and the drill pipe 90 drives the connecting disc body 21, the torque transmission bar 23, the driving cylinder 22, the suspension cylinder 31, and the annulus sealing device 91 to descend, the annulus sealing device 91 is then sleeved on an outer wall of the casing hanger 92, and the second boss part 414 on the top of the piston 41 passes into the through-hole 222 of the driving cylinder, the driving cylinder 22 and the piston 41 form a piston sealing structure 63, forming a hydraulic auxiliary piston;
Step g: the drill pipe 90 drives the spindle 1, the connecting disc body 21, the torque transmission bar 23, the driving cylinder 22, and the suspension cylinder 31 to continue to descend, a volume of the piston cavity 40 further decreases, and a pressure in the piston cavity 40 increases, and under the pressure in the piston cavity 40, the valve core 52 moves upward, the second passage hole 522 communicates with the inner cavity of the spindle 1 through the valve body communication hole 512 and the first communication through-hole 13, the piston cavity 40 below the valve core 52 communicates with the inner cavity of the spindle 1, and the fluid in the piston cavity 40 flows into the inner cavity of the spindle 1; the drill pipe 90 continues to descend and when the vertical displacement of the drill pipe 90 reaches a predetermined displacement, the top end surface of the second boss part 414 pushes the valve core 52 upward; the piston cavity 40 is always in communication with the inner cavity of the spindle 1 through the second passage hole 522, the valve body communication hole 512 and the first communication through-hole 13;
Step h: operate a hydraulic equipment at a derrick to pressurize the interior of the drill pipe 90, a high-pressure fluid (after operating the hydraulic equipment at the derrick to pressurize the interior of the drill pipe 90, the fluid has an elevated pressure to form the high-pressure fluid) enters into the piston cavity 40 through the first communication through-hole 13 and the valve body communication hole 512, and the driving cylinder 22 shears off the shear pin 25 and continues to descend under the drive of the high-pressure fluid;
Step i: a bottom end surface of the driving cylinder 22 transmits the hydraulic pressure to the annulus sealing device 91, the annulus sealing device 91 seals the annulus space between the subsea wellhead and the casing hanger 92, and thereby the annulus below the annulus sealing device 91 is separated from the upper wellbore, as shown in
Step j: stop pressurization, apply an axial tension to the drill pipe 90, to drive the spindle 1, the connecting disc body 21, the torque transmission bar 23, and the suspension cylinder 31 to move upward, and the elastic pins 32 are cut off under the action of the axial tension, and thereby the casing hanger and annulus sealing device running tool for deepwater drilling 100 releases from the annulus sealing device 91; and
Step k: lift the drill pipe 90, to raise the casing hanger and annulus sealing device running tool for deepwater drilling 100 out of the subsea wellhead and to a derrick, completing installations of the casing hanger 92 and the annulus sealing device 91.
From the above, the casing hanger and annulus sealing device running tool for deepwater drilling and the use method thereof provided by the present invention include the following beneficial effects:
the casing hanger and annulus sealing device running tool for deepwater drilling of the present invention can realize the requirements of installing the casing hanger and the annulus sealing device at the subsea wellhead on the seafloor, and fully use the torque transmission structure, the suspension structure, the hydraulic piston structure and the lead screw nut structure in combination, where the suspension cylinder can rotate to hook to and rotate to release the annulus sealing device, the bottom of the piston can hook to and release the casing hanger, the hydraulic piston structure can apply a driving force to the annulus sealing device, and the sealing and releasing of the annulus sealing device and the casing hanger can be achieved by a method of rotating the drill pipe. The casing hanger and annulus sealing device running tool for deepwater drilling of the present invention has less difficulty in operation, and the method for using the same has simple implementation steps, high installation reliability, and low cost, which is conducive to popularization and use.
The above descriptions are merely exemplary embodiments of the present invention, and are not intended to limit the scope of the present invention. Any equivalent changes and modifications made by those skilled in the art without departing from the concept and principle of the present invention shall fall within the protection scope of the present invention.
Number | Date | Country | Kind |
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201810389708.9 | Apr 2018 | CN | national |
This application is a continuation of International Application No. PCT/CN2018/107292, filed on Sep. 25, 2018, which claims the priority benefit of China Patent Application No. 201810389708.9, filed on Apr. 27, 2018. The contents of the above identified applications are incorporated herein by reference in their entireties.
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Entry |
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International Search Report dated Jan. 31, 2019 in corresponding International application No. PCT/CN2018/107292; 5 pages. |
Number | Date | Country | |
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20200370387 A1 | Nov 2020 | US |
Number | Date | Country | |
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Parent | PCT/CN2018/107292 | Sep 2018 | US |
Child | 16923429 | US |