Patent Grant
12049800
The present disclosure relates to pressure control tools. Specifically, the present disclosure relates to systems and methods for setting a secondary pressure boundary tool for a downhole application.
Hydrocarbon exploration may be conducted at surface or offshore locations and may include various pressure boundaries between a formation and an access location. Often, a tree, which may be referred to as a Christmas tree (XT), is arranged at the access location and includes a series of valves that may work with additional vales associated with the wellbore, such as downhole valves. Servicing these valves may include blocking in one or more downhole valves in order to create a sufficient number of pressure boundaries between the wellbore and the access location. Operations associated with downhole valves may be time consuming and costly because they use additional trips into and out of the wellbore.
Applicant recognized the problems noted herein and conceived and developed embodiments of systems and methods, according to the present disclosure, for wellbore pressure boundary systems.
In an embodiment, a system includes a pressure boundary tool and an installation and retrieval tool. The pressure boundary tool includes a plug body, the plug body having an orifice extending from a first end to second end. The pressure boundary tool also includes a plate coupled to the second end via one or more fasteners, the plate positioned for axial movement along an axis of the pressure boundary tool. The pressure boundary tool further includes a seal arranged within a seal groove formed between the plug body and the plate. The pressure boundary tool also includes a retaining assembly positioned at the second end within the orifice. The pressure boundary tool includes a capture plate arranged over the retaining assembly to maintain a position of the retaining assembly within the orifice. The installation and retrieval tool includes a shaft having first threads on a first shaft end and being non-threaded at a second shaft end, the threads configured to engage mating threads of the plate. The installation and retrieval tool also includes a sleeve having second threads on a first sleeve end and couplers on a second sleeve end, the second threads configured to engage the plug body and the couplers configured to engage the retaining assembly. The first threads and the second threads are configured for use during an installation process and the couplers are configured for use during a retrieval process.
In an embodiment, a system includes a Christmas tree (XT) having at least one valve, the XT being coupled to a wellbore. The system also includes a pressure boundary tool adapted to provide a secondary boundary for the XT. The pressure boundary tool includes a plug body to be positioned against a valve member of the at least one valve; a seal to be energized into a valve body of the at least one valve; and a plate arranged proximate the seal, the plate being moveable between a first position and a second position, the first position energizing the seal and a second position deenergizing the seal. The pressure boundary tool is positioned within the XT on a side of the valve member closer to the wellbore.
In an embodiment, a method includes coupling an installation and retrieval tool to a pressure boundary tool. The method also includes opening a specified valve of a Christmas tree (XT). The method further includes running the pressure boundary tool past a valve member of the specified valve. The method also includes energizing a seal of the pressure boundary tool. The method includes decoupling the installation and retrieval tool from the pressure boundary tool. The method further includes removing the installation and retrieval tool from a flow passage of the specified valve. The method also includes closing the specified valve.
The present technology will be better understood on reading the following detailed description of non-limiting embodiments thereof, and on examining the accompanying drawings, in which:
The foregoing aspects, features, and advantages of the present disclosure will be further appreciated when considered with reference to the following description of embodiments and accompanying drawings. In describing the embodiments of the disclosure illustrated in the appended drawings, specific terminology will be used for the sake of clarity. However, the disclosure is not intended to be limited to the specific terms used, and it is to be understood that each specific term includes equivalents that operate in a similar manner to accomplish a similar purpose.
When introducing elements of various embodiments of the present disclosure, the articles “a”, “an”, “the”, and “said” are intended to mean that there are one or more of the elements. The terms “comprising”, “including”, and “having” are intended to be inclusive and mean that there may be additional elements other than the listed elements. Any examples of operating parameters and/or environmental conditions are not exclusive of other parameters/conditions of the disclosed embodiments. Additionally, it should be understood that references to “one embodiment”, “an embodiment”, “certain embodiments”, or “other embodiments” of the present disclosure are not intended to be interpreted as excluding the existence of additional embodiments that also incorporate the recited features. Furthermore, reference to terms such as “above”, “below”, “upper”, “lower”, “side”, “front”, “back”, or other terms regarding orientation or direction are made with reference to the illustrated embodiments and are not intended to be limiting or exclude other orientations or directions. It should also be appreciated that dimensions, angles, and other components may be referred to as being substantially within a range of approximately plus or minus 10 percent.
Embodiments of the present disclosure are directed toward systems and methods that may be used to provide secondary pressure boundaries to a wellbore system, such as to a Christmas Tree (XT) (e.g., tree) associated with a wellbore. The secondary pressure boundary may be a removable pressure boundary that may be added or removed from the XT to facilitate one or more maintenance operations, such as replacement or repair of components associated with the XT. In various embodiments, the secondary pressure boundary is installed through an existing valve, such as a gate valve, and then seals against one or more portions of the valve, such as against a valve body. Moreover, after installation, the valve may still be operable due to removal of installation tools, thereby maintaining the pressure boundary provided by the associated valve. One or more embodiments enable servicing and operations of the XT above a lower master valve without trips into the wellbore to shut downhole valves. One or more embodiments enabling serving and operations of one or more wellbore components above a selected valve without additional trips into the wellbore to shut downhole valves.
In this example, the XT 102 includes a number of valves for controlling a flow of fluid, such as a production fluid, into and out of the wellbore. The valves may include master valves, wing valves, swab valves, crown valves, and the like. In this example, the XT includes a lower master valve 106, an upper master valve 108, a wing valve 110 (e.g., a kill wing valve), a wing valve 112 (e.g., a production wing valve), and a swab valve 114 (e.g., a crown valve). Additionally tree components also include a surface choke 116, a tree adapter 118, and a gauge 120. It should be appreciated that the configuration of
During wellbore operations, it may be desirable or necessary to service one or more components of the XT 102. For example, valves may be replaced or serviced, different flow lines may be added, and the like. As a result, the wellbore is closed in or otherwise isolated prior to operations on the XT. Shutting in the wellbore typically includes one or more trips into the wellbore, where a tool may be lowered in through the XT 102 and then engaged, such as a packer that blocks flow or activates one or more other systems. These operations are typically costly and time consuming, as each trip into the wellbore may take several hours. However, such trips are often necessary to comply with industry standards regarding wellbore isolation, as having more pressure boundaries is desirable prior to working on the XT 102. Systems and methods of the present disclosure may include one or more boundary tools that enable installation of a secondary boundary associated with the XT 102, such as at the lower master valve 106, among other locations. However, it should be appreciated that embodiments of the boundary tools may be installed at any appropriate location.
Systems and methods may include a pressure boundary tool that is installed through one or more portions of the XT 102, such as through the tree adapter 118, to a desired location, such as a location associated with one or more of the valves. For example, the selected vale may be the lower master valve 106, which may be in an open or partially open position as the pressure boundary tool is run through the XT 102. Once positioned at the desired location, the lower master valve 106 (or any other associated valve) may be partially closed to facilitate positioning of the pressure boundary tool, such as arranging the pressure boundary tool such that one or more portions of the valve contact one or more portions of the pressure boundary tool (e.g., an outer sleeve as will be described herein). Such a positioning may be useful to enable the master valve 106 to maintain operational capabilities after installation of the pressure boundary tool. A plug body may then be driven in an uphole direction to contact a valve member of the lower master valve 106 and a plate may be driven against the plug body to compress a seal against a valve body. Once positioned, the running tool associated with the pressure boundary tool may be decoupled from the plug body and retrieved, thereby permitting operations above the lower master valve 106. By activating both the pressure boundary tool and the lower master valve 106, a double pressure boundary may be set below the remaining tree components.
In at least one embodiment, systems and methods may permit retrieval and removal of the pressure boundary tool. For example, the tool described above may have an installation end and a retrieval end positioned at opposite ends of the tool. During installation, the installation end may be coupled to the plug body. However, during retrieval, the tool may be flipped so that the retrieval end engages the plug body. The different ends may use different coupling mechanisms. For example, the installation end may use one or more threaded fittings because there may be a reduced risk of misalignment when aligning threaded fittings at a surface location prior to installation. However, they retrieval end may use different coupling mechanisms, such as various grooves or press fitting configuration. The engagement with the plug body may be via a collect interface, among other options. Thereafter, a piston may be threaded to deactivate the seal to permit movement away from the valve member. Additionally, in various embodiments, one or more manual operations may be used to deactivate the seal. Accordingly, the valve member may be opened and the pressure boundary tool may be removed, permitting further operations.
A seal 208 (e.g., annular seal, seal assembly) is positioned axially, along a tool axis 210, between the plug body 202 and the plate 204. The seal 208 may be formed from any suitable material, such as an elastomer. It should be appreciated that the inclusion of a single annular seal 208 is for illustrative purposes only and that, in other configurations, that may be a stack or seals 208 and/or additional seals with associated components, such as additional plates. For example, the plate 204 may compress against a first seal, which compresses against a second plate, which compresses against a second seal, which compresses against the plug body 202. In this manner, additional sealing capabilities may be provided and/or redundancy may be incorporated to reduce a likelihood of a failure to energize or set the seals. In operation, energizing or setting the seal 208 may refer to apply a pressure to the seal 208 such that the seal expands axially to contact a surrounding body to form a pressure barrier to block fluid flow. The seal 208 is arranged within a seal groove 212, which is a reduced diameter portion of the plug body 202 such that a seal groove diameter 214 is less than a body outer diameter 216. In this configuration, a plate contact area 218 is sized to fit within the seal groove 212 and to compress the seal 208 via one or more extensions 220. In this example, the extensions 220 are sized such that a first plug end 222, opposite a second plug end 224, fits within a recess 226 formed between the extensions 220. In various embodiments, a plate outer diameter 228 is substantially equal to the body outer diameter 216, but it should be appreciated that the plate outer diameter 228 may be greater than or less than the plug outer diameter 216 in other embodiments.
The illustrated tool 200 is coupled to an installation and retrieval tool 230 that may be utilized to both install the tool 200 within the XT 102 and/or one or more components associated with the XT 102. In this example, the installation and retrieval tool 230 includes an installation end 232 and a retrieval end 234, which different ends 232, 234 are used during installation and retrieval operations. In this example, the installation end 232 is coupled to the tool 200. A shaft 236 of the installation and retrieval tool 230 is shown coupled to the plate 204, for example via threads. It should be appreciated that a threaded connection is shown as an example and different couplings may be used in other configurations. The shaft 236 extends through a variable diameter orifice 238, which includes a first region 240 and a second region 242. A distance along the axis 210 between the first region 240 and the plate 204 is less than a distance along the axis 210 between the second region 242 and the plate 204. In other words, the illustrated first region 240 is closer to the plate 204 than the second region 242. As will be discussed herein, one or more components may be positioned within the first and second regions 240, 242 to facilitate coupling between the shaft 236 and/or a sleeve 244 and the body 202.
The tool 230 further includes the sleeve 244, through which the shaft extends 236. A nut 246 is also coupled to the shaft 236 proximate the retrieval end 234 that may, when rotated, drive axial movement of the shaft 236 along the axis 210. For example, rotation of the nut 246 may drive the shaft 236 in a direction away from the plate 204, thereby driving the plate 204 toward the nut 246 and compressing the seal 208. As will be described below, in various embodiments the tool 230 may be removed and then flipped 180 degrees so that the retrieval end 234 may engage the plate 204 and/or the plug body 202 to deenergize the seal 208 and permit removal of the tool 200.
The pressure boundary tool 200 is shown in an un-set position (e.g., a deenergized position) where the seal 208 has not been compressed by the plate 204. Accordingly, the pressure boundary tool 200 may be moved along the axis 210 to a desired location, for example, to a position where the seal 208 is aligned with the valve body 302. That is, a plug body length 310 may be longer than a valve seat length 312 of a valve seat 314 so that the seal 208 seals against the valve body and not the valve seat 314. It should be appreciated that, in various embodiments, the seal 208 may seal against the valve seat 314.
One or more embodiments may include an indicator along at least one of the shaft 236 and/or the sleeve 244 to assist with placing the pressure boundary tool 200. For example, a marker may be arranged on the shaft 236 that is aligned with the nut 246 when the pressure boundary tool 200 is positioned at a pre-determined location. Such an indicator may reduce a likelihood of damage to the valve set 206 when it is closed, at least partially, and/or may reduce a likelihood of misplacement and realignment of the pressure boundary tool. 200. Various types of indicators may be used with embodiments of the present disclosure, such as different colors along the shaft 236, a fitting that is placed on the shaft 236 that contacts the nut 246 at the desired location, and the like. In at least one embodiment, a position of the pressure boundary tool 200 may, at least partially, be verified by partially closing the valve member 206 such that the valve member 206 contacts the sleeve 244. For example, because the body diameter 216 is larger than an associated sleeve diameter, the valve member 206 will not move as far if the plug body 202 is in the way, as compared to the sleeve 244. This may provide as a secondary check (or the primary check) and may be used as additional verification, along with or in place of, the indicator.
In various embodiments, the plug body 202 may be pulled or otherwise driven back and toward the valve member 306 such that the second plug end 224 contacts the valve member 306. In various embodiments, one or more disks 316 may be arranged at the second plug end 224 to prevent damage to the valve member 306. For example, the disk 316 may be formed from a soft material (e.g., softer than the valve member 306) to prevent damage. The disk 316 may be fastened to the second plug end 224 by a variety of methods, such as a counter-sunk screw, as one example.
Further illustrated are the fasteners 206 extending between the plug body 202 and the plate 204. The fasteners 206 are arranged within a passage 320 formed within the plug body 202 that also includes an opposite fastener 322 for securing a capture plate 324 to the plug body 202 at the second end 224. It should be appreciated that inclusion of both the fastener 206 and an associated opposite fastener 322 within a common passage 320 is shown for illustrative purposes and the fasteners 206, 322 may not share a common passage 320. However, using a common passage may simplify installation and assembly, as well as manufacturing. The illustrated capture plate 324 is positioned within a recess 326. As will be described, the capture plate 324 may be used to secure a collet configuration within the orifice 238 to facilitate removal without threading the retrieval end 234 to the plug body 202. The disk 316 is shown as covering the capture plate 324, which as noted above, may decrease a likelihood of damage to the valve member 306 during operations. Now illustrated are fasteners that may be used to secure the disk 316 to the plate 324 and/or the plug body 202. It should be appreciated that various other coupling mechanisms may also be used.
In this example, the orifice 328 includes the first region 240 and the second region 242, where the first region 240 is proximate the plate 204 and the second region is proximate the capture plate 324. The first region 240 may facilitate coupling of the shaft 236 to the plate 204, for example through a threaded connection. The second region 242 receives the shaft 236 and the sleeve 244, where the sleeve 244 may abut against a stop shoulder 328. It should be appreciated that the sleeve 244 may also be threaded to the plug body 202. Further positioned within the second region 242 is a collet assembly 330, which may be utilized during removal operations. For example, in this configuration, the shaft 236 and the sleeve 244 may pass through the collet assembly 330, but during removal, the collet assembly 330 may engage the retrieval end 234 of the tool 230.
In the illustrated configuration, the installation end 232 is shown engaging the plate 204. For example, one or more threads may be utilized to couple to mating threads of the 204, but other coupling mechanisms may also be used, such as bayonet connections, tongue and grooves, dogs, and the like. In this example, an anti-rotation mechanism 332 is positioned within the first region 240. The anti-rotation mechanism may block rotation of the body 202 with respect to the shaft 236 during removal of the installation end 232. For example, one or more pins may extend outwardly such that rotation of the shaft 236, for example due to the nut 246, is not transmitted to the plug body 202. It should be appreciated that various other anti-rotation pins or mechanisms may be utilized to block rotation of various components.
As noted above, the installation and retrieval tool 230 may include two opposite ends, where the installation end 232 shown in
In operation, the movement of the plate 204 may be driven, at least in part, by the nut 246. For example, the nut 246 may be rotated to drive the shaft 236 in a direction such that the plate 204 moves toward the plug body 202. As noted above, the plug body 202 may be driven against the valve member 306, and as a result, the plug body 202 may remain stationary as the plate 204 moves, thereby compressing the seal 208 to engage the valve body 302. For example, the rotation of the nut 246 may cause the shaft 236 to travel along the sleeve 244, and due to the connection of the sleeve 244 and plug body 202, the shaft 236 travels such that the plate 204 is driven toward the plug body 202.
Prior to removal, the seal 208 is deenergized. In other words, the plate 204 is driven away from the plug body 202 so that the seal 208 is no longer compressed against the valve body 302. In this example, a piston 602 is attached to the tool 230 to provide an axial force along the axis 210 in drive the plate 204 away from the plug body 202. Accordingly, removal steps may include opening the valve to remove the valve member 302 from the flow passage 304, engaging the collet assembly 330 via one or more grooves, while other portions are not threaded to the tool 230, coupling the piston 602 to the tool 230, and then applying a force to the plate 204 to deenergize the seal 208. It should be appreciated that the piston 602 is shown as an example and that other embodiments may utilize different mechanisms to deenergize the plate 204, including but not limited to manual methods.
As noted above, the retrieval end 234 is used, rather than the installation end 232. Advantageously, these may be different ends of the same tool 230, thereby eliminating a need to have different components at the site for installation and removal. Moreover, by eliminating threads from the retrieval end 234, there may be a reduced likelihood of damage or error during the retrieval process. For example, it may be challenging to properly engage threads.
The pressure boundary tool may be set for installation at a designated location within wellbore system, such as the XT 102, and an associated value may be opened 804. In at least one embodiment, the valve may be a gate valve, where a gate may be removed from a flow passage to permit passage of the pressure boundary tool. The pressure boundary tool may be run past a valve member to a desired location 806. For example, the pressure boundary tool may be tripped through the XT 102 to position the pressure boundary tool on a downstream side of the valve member 306. The location of the pressure boundary tool may be determined based, at least in part, on a valve body position with respect to a valve seat 314, where certain embodiments may particularly select locations past valve seats 314 as sealing surfaces for the seal 208.
The pressure boundary tool may be set against the valve member 808. For example, a plug body 202 may be pulled against the valve member 306 such that a disk 316 engages the valve member 306. As noted, the disk 316 may be a soft material in order to prevent damage to the valve member 306. The seal may then be energized 810. For example, the plate 204 may be driven toward the plug body 202, such as via rotation of a nut 246 to drive movement of an associated shaft 236. The movement of the plate 204 may reduce or collapse a gap 318 between the plate 204 and the plug body 202, thereby compressing the seal 208 outwardly and against the valve body 302.
When the seal is set, the installation and retrieval tool may be decoupled from the pressure boundary tool 812. For example, one or more threaded connections may be reversed or broken, where certain embodiments may include anti-rotation pins to facilitate the decoupling. The installation and retrieval tool may then be removed 814 and the valve may be closed 816. In this manner, a secondary pressure boundary is positioned within the XT 102.
The foregoing disclosure and description of the disclosed embodiments is illustrative and explanatory of the embodiments of the disclosure. Various changes in the details of the illustrated embodiments can be made within the scope of the appended claims without departing from the true spirit of the disclosure. The embodiments of the present disclosure should only be limited by the following claims and their legal equivalents.
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