The disclosure generally relates to the field of subsurface operations, and more particularly to a self-orienting selective lockable assembly to regulate subsurface depth and positioning.
An anchoring device (e.g., a packer or liner hanger) may be set in a casing string in a parent wellbore and inhibit movement of itself or attached tools. An anchoring device may be useful for downhole applications requiring an immobile subsurface platform. An anchoring device can act as a seal and provide pressure isolation for a zone of a parent wellbore below an intersection with a branch wellbore. In some applications, an anchoring device can be a secure platform upon which a whipstock is attached when milling through the casing of the parent wellbore and drilling the branch wellbore.
Embodiments of the disclosure may be better understood by referencing the accompanying drawings.
The description that follows includes example systems, methods, techniques, and operations that embody aspects of the disclosure. However, it is understood that this disclosure may be practiced without these specific details. For instance, this disclosure refers to a system application for subsurface operations. But aspects of this disclosure can be also applied to various other types of applications that are above surface. In other instances, well-known structures and techniques have not been shown in detail in order not to obfuscate the description.
Various embodiments include a set of tools or components that can be combined into an assembly that can be lowered to a downhole/subsurface location such that there is control of both depth and azimuthal positioning of devices attached to the assembly. Such control can be provided without rotation, from the surface or at any point along the wellbore such as via tubing, pipe, or other mechanisms. The attached devices can include various bottom hole assemblies (BHAs) that can require specific depth and more importantly azimuthal or directional control. An example of a BHA includes a whipstock, which may be used to deflect drill bits towards a new direction by guiding a drill bit through a milling window on the whipstock.
In some embodiments, the combined assembly can be a self-orienting selective lockable latch assembly. Relative orientation between this assembly and the attached device can be established at the surface. After the assembly and the attached device are lowered downhole and the assembly is locked in place, the attached device is positioned at the proper depth and azimuthal orientation to allow the attached device to perform its operation properly. As further described below, this proper depth and azimuthal orientation of the assembly and attached device can be performed without tubing rotation from the surface. Accordingly, various embodiments do not require the application of torque to the downhole tubing to provide proper depth and azimuthal orientation.
Additionally, for the self-orienting selective lockable latch assembly, there are no pre-alignment (orientation or otherwise) requirements relative to any of its components. Rather, there can be alignment requirements relative to devices being attached to the assembly. Also, as further described below, various embodiments allow for the locking of the assembly to support and resist both upward and downward movement while in operation.
Example System
The well system includes a platform 106 positioned on the earth's surface 104 and extending over and around the wellbore 114. The wellbore 114 extends vertically from the earth's surface 104. The lower latch orientation housing 150 can include, optionally, a set of spacer casing 156 may be used to extend the length between the latch coupling 152 and orientation housing 154, which may enhance stability of the well system during running or locking procedure.
The upper latch orientation housing 140 includes an upper latch coupling 142, an upper orientation housing 144, and, optionally, an upper set of spacer casing 146. The upper latch orientation housing 140 is positioned above the latch orientation housing 150. As will be expanded in the descriptions below, this upper latch orientation housing 140 may allow the self-orienting selective lockable latch tool 160 to pass through without engaging any locking mechanisms or causing irreversible damage to the self-orienting selective lockable latch tool 160. Before installation of the self-orienting selective lockable latch tool 160, the wellbore tubular system 120 may be surveyed in order to help plan the azimuthal directions of the self-orienting lockable latch tool 160, especially with regards to the azimuthal direction of the orientation housing 154 and the upper orientation housing 144.
The self-orienting selective lockable latch tool 160 will be lowered until the tool has been lowered to the depth of the latch orientation housing 150. After performing a locking operation to be described below, the self-orienting selective lockable latch tool 160 is locked to the latch orientation housing 150. Though the upper latch coupling 142 and the latch coupling 152 are identical in
This capability of the self-orienting selective lockable latch tool 160 to be universally compatible with a plurality of potential latch couplings in the well provides greater design flexibility for initial well planning or later well projects. In this case, a well project may rely on the self-orienting selective lockable latch tool 160 to run through latch couplings not at the target depth such as the upper latch orientation housing 140 without locking. When the self-orienting selective lockable latch tool 160 is lowered to the target position, upward loading is applied to return the self-orienting selective lockable latch tool 160 to the target position. For example, upward loading may be applied onto a drillstring attached to the top the self-orienting selective lockable latch tool 160, wherein the tool may be moved upward toward the earth's surface 104. As this upward loading is applied, the orientation tool 164 will ensure that the self-orienting selective lockable latch tool 160 remains oriented in a planned direction during any operation due to the rotational force exerted on the orientation tool 164 by the orientation housing 154. As further described below, further upward load will activate an internal support decoupling mechanism in the selective lockable latch tool 162 and subsequent run-in loading will lock the tool in place. This will prevent axial motion of the self-orienting selective lockable latch tool 160 and the whipstock tool 122. During the entirety of the locking operation, only axial force was applied and the locking operation did not require exertion of torque from the surface. Once locked, the self-orienting selective lockable latch tool 160 may be used to provide a stable platform to ensure positive regulation of depth and azimuthal positioning for the whipstock or any other attached tools without further intervention or surface manipulation.
Example Self-Orienting Selective Lockable Latch Tool
The following figures will depict various elements first illustrated in
Rigidly attached to the orientation tool 164 is the selective lockable latch tool 162. Elements of the selective lockable latch tool 162 allows for axial locking of the self-orienting selective lockable latch tool 160 into the latch orientation housing 150. A set of circumferential latch keys 206 radially protrude from the selective lockable latch tool 162, and may be comprised of rounded, squared, planar, or curved shoulders shaped to resist moderate loading when operably engaged with a latch coupling key profile 208. The latch coupling key profile 208 may be comprised of a set of circumferential grooves on the inner surface of the latch coupling, and may be designed to match the shape and size of the set of circumferential latch keys 206. However, increased rightward loading will cause the set of circumferential latch keys 206 to flexibly compress inwards when forced into a location narrower than those allowed by the latch coupling key profile 208. Likewise, a set of movable circumferential dogs 210, which is fitted inside of slots along a lockable latch dog housing 232, may be flexibly pushed inwards when the selective lockable latch tool 162 is being run in the rightward direction. The movable circumferential dogs 210 may be distributed around the selective lockable latch tool 162 and compressed inwards when it is forced into a location with a diameter narrower than that of a latch coupling internal circumferential shoulder 212. Moreover, because both the circumferential latch keys 206 and movable circumferential dogs 210 may be reversibly compressed, a plurality of identical or unique latch couplings may be passed through without locking the selective lockable latch tool 162.
During a locking operation, the first physical load change will be an upward load on the selective lockable latch tool 162. In
Further upward loading towards the surface end (i.e., the leftward end in
In some embodiments, upon renewed loading in the downhole direction after the shearing of the set of shear pins 308, the slidable support element 334 will slide along a second splined element 314 on the inner mandrel 310 in the rightward direction. The second splined element 314 may also be positioned as a part of the outer colleted cylindrical housing 306. The circumferential latch keys 206 may engage or continue to remain engaged with the latch coupling key profile 208, preventing components that are attached to the circumferential latch keys 206 from moving with the slidable support element 334. A set of snap rings 312 acts as fastening elements and will secure the slidable support element 334 in a support locking position 318 that will lock the slidable support element 334 in place as a locking mechanism. The position of the slidable support element 334 underneath the circumferential latch keys 206 prevents inward movement, securing both the slidable support element 334 and the selective lockable latch tool 162 against rightwards movement. Having thus been secured against both leftward and rightward motion, the selective lockable latch tool 162 may be locked in place without external application of torque.
Example Operations
At block 1202, the casing of the wellbore is lowered into the well with an orientation housing until the orientation housing has reached a pre-defined position. For example, with reference to
At block 1204, a determination is made on whether a segment of a casing being inserted will be at a targeted lock position when installed in the casing. In one non-limiting example, with reference to
In the case that the segment added will not be at the targeted lock position upon setting, the procedure will continue to block 1206 and a segment of casing will be run into the wellbore and then proceed to block 1216.
However, if the segment added will be at a targeted lock position upon setting, the procedure will move to block 1208, wherein a lower orientation housing is used in place of ordinary casing and is run into the wellbore.
At block 1210, a determination is made of whether a spacer casing is added on top of the orientation housing. In particular, a determination is made on whether the orientation housing and the latch coupling are to be directly connected or if one or more spacer casings will be inserted between the orientation housing and the latch coupling. Such spacer casing may be advantageous to enhance stability of the self-orienting selective lockable latch tool. With reference to
At block 1212, the spacer casing is lowered into the wellbore to be positioned above the orientation housing. This may occur after the orientation housing has already been physically set in place, or by lowering a combined tubular assembly comprised of both the spacer casing and the orientation housing, with the orientation housing lower than the spacer casing.
At block 1214, the latch coupling is lowered into the wellbore above the orientation housing and, if present, the spacer casing. For example, with reference to
At block 1216, a determination is made of whether there is additional casing and/or locking assemblies to be run into the well. For example, with reference to
Any combination of orientation housing, casing, or universal latch coupling, or plurality thereof, may be physically connected above the surface before being run into a well, or may be individually run into the well and connection established within the wellbore.
Upon installation of latch coupling and orientation housing into the well, there may be an assessment of the orientation at least one of the orientation housing at 1320. Such an assessment can be performed through use of a dummy tool, MWD equipment, or with a universal bottomhole orientation tool. At 1322, the orientation tool 164 is selected and prepared to be run in based on the known properties of the orientation housing 154. At 1324, it is determined whether the orientation tool 164 and the selective lockable latch tool 162 are to be directly connected or if spacer tubing is required to ensure that the orientation tool 164 may be positioned into the orientation housing 154 while the selective lockable latch tool 162 is positioned in the latch coupling 152.
If spacer tubing is required, then the spacer tubular 166 will be attached between the orientation tool 164 and the selective lockable latch tool 162 at block 1326. After the spacer tubular 166 is attached to the orientation tool 164, the selective lockable latch tool 162 is attached to the spacer tubing at 1328 to form the self-orienting selective lockable latch tool 160. If spacer tubing will not be used between the orientation tool selective lockable latch tool, then a selective lockable latch tool is attached directly to the orientation tool at 1328, assembling a self-orienting selective lockable latch tool without spacer tubing.
At 1330, a drilling operator may optionally attach one or more additional tools to the self-orienting selective lockable latch tool 160. The self-orienting selective lockable latch tool 160 may then be run into the well until a target locking position is reached by the tool at 1332. At 1334, the operational parameters such as lowering speed or force applied may be modified to allow the lockable latch tool 160 to self-orient. Then at 1336, upward loading substantially parallel to the wellbore axis is applied on the self-orienting selective lockable latch tool 160 to free the slidable support element 334 from its first position. Once the slidable support element 334 is first freed, we apply run-in loading from the surface until the slidable support element 334 is locked into the support locking position 318 by the set of snap rings 312 during a second locking step 1338. At 1340, the self-orienting selective lockable latch tool 160 is removed from the well by applying upward loading from the surface until both the set of snap rings 312 and the set of shear pins 324 are sheared and the tool is pulled back towards the wellbore surface.
Example Embodiments
Some embodiments may include an apparatus comprising a cylindrical housing with a circumferential radially compressible protrusion, a mandrel coaxial with the cylindrical housing and forming an annular volume between an inner surface of the cylindrical housing and the mandrel, a circumferential support element that is at least partially within the annular volume that is to reinforce the circumferential radially compressible protrusion against compression, and a movable circumferential dog attached coaxially to the cylindrical housing and is reversibly compressible into an axis of the cylindrical housing.
In some embodiments, the circumferential radially compressible protrusion has a planar face with a surface norm facing towards one end of the cylindrical housing.
In some embodiments, the apparatus further comprises of a circumferential component attached to the circumferential support element, wherein the circumferential component is to slidably move along the axis of the cylindrical housing.
In some embodiments, the apparatus further comprises of a first splined element is attached to at least one of the circumferential support element and the circumferential component, the first splined element to operably engage with a second splined element attached to at least one of the cylindrical housing and the mandrel to limit rotational movement of the circumferential support element.
In some embodiments, the apparatus further comprises of a first releasable connection element that fastens the circumferential support element to a locked position within the annular volume where the circumferential support element reinforces the circumferential radially compressible protrusion against radial compression, and a second releasable connection element that fastens the circumferential support element to an unlocked position within the annular volume where the circumferential support element does not reinforce the circumferential radially compressible protrusion against radial compression.
In some embodiments, the first releasable connection element is a shear pin and the second releasable connection element is a snap ring.
In some embodiments, the apparatus further comprises of a circumferential raised element radially beneath the dog housing tubular assembly and positioned to physically reinforce the movable circumferential dog against radial compression, a first surface of the circumferential raised element with a first surface norm facing radially away from a first axial direction, and a second surface of the circumferential raised element with a second surface norm facing towards the first axial direction.
In some embodiments, the apparatus further comprises of a compressed spring positioned to move the movable circumferential dog axially upon shearing of the third releasable connection element.
In some embodiments, a system comprises of a first tubular housing with a circumferential latch profile and an internal circumferential shoulder disposed on an inner surface of the first tubular housing, a second tubular housing attached to one end of the first tubular housing, with at least one orientation profile disposed on an inner surface of the second tubular housing, an orientation tool positionable within the second tubular housing, wherein a protrusion is operably engageable with the orientation profile of the second tubular housing, a cylindrical housing with a circumferential radially compressible protrusion that is attached to the orientation tool, a mandrel coaxial with the cylindrical housing and forming an annular volume between the inner surface of the cylindrical housing and the mandrel, a circumferential support element that is at least partially within the annular volume that reinforces the circumferential radially compressible protrusion against compression; and a movable circumferential dog attached coaxially to the cylindrical housing and is reversibly compressible into the axis of the cylindrical housing.
In some embodiments, the system further comprises of a muleshoe attached to the inner surface of the second tubular housing, an orientation profile disposed on the inner surface of the second tubular housing and parallel to the axis of the second tubular housing; and the orientation tool, wherein the orientation tool possesses a single orientation protrusion that is shaped to operably engage with the orientation profile.
In some embodiments, a first length of casing string is positioned between the first tubular housing and second tubular housing and a second length of tubing is positioned between the orientation tool and the cylindrical housing.
In some embodiments, the system further comprises of a first releasable connection element that fastens the circumferential support element to a locked position within the annular volume where the circumferential support element reinforces the circumferential radially compressible protrusion against radial compression, and a second releasable connection element that fastens the circumferential support element to an unlocked position within the annular volume where the circumferential support element does not reinforce the circumferential radially compressible protrusion against radial compression.
In some embodiments, the circumferential latch profile further comprises of a set of circumferential grooves that operably engages with the circumferential radially compressible protrusion.
In some embodiments, the system further comprises of an upper tubular housing with an upper circumferential latch profile that operably engages with the circumferentially radially compressible protrusion.
In some embodiments, the system further comprises of an upper tubular housing with an upper circumferential latch profile that operably engages with the circumferentially radially compressible protrusion.
In some embodiments, a method comprises of lowering a well tool with a cylindrical housing into a well until the cylindrical housing is positioned inside of a first tubular housing, applying an axial upward load on the well tool to operably engage a movable circumferential dog attached to the well tool with an internal shoulder attached to an inner surface of the first tubular housing, applying axial upward load on the well tool to release a first releasable connection element that is fastening a circumferential support element to an unlocked position within an annular volume inside of the well tool, and applying axial run-in load on the well tool to slidably move the circumferential support element until a second releasable connection element fastens the circumferential support element to a locked position in the annular volume and supports a circumferential radially compressible protrusion on the cylindrical housing against compressing inwards.
In some embodiments, the method further comprises of running the well tool to an upper tubular housing, wherein the circumferential radially compressible protrusion operably engages with an upper circumferential latch profile on the upper tubular housing, and running the well tool through the upper tubular housing until it reaches the first tubular housing.
In some embodiments, the method further comprises of applying axial upward load on the circumferential support element to release the second releasable connection element that is fastening the circumferential support element.
In some embodiments, the method further comprises of applying axial upward load on the circumferential support element to release a third releasable connection element attached to the movable circumferential dog that is fastening the movable circumferential dog.
In some embodiments, the method further comprises of using an orientation tool attached to the cylindrical housing to operatively engage with an orientation profile of an orientation tubular.
In some embodiments, the method further comprises of attaching a third tool above the cylindrical housing such that torque experienced by the third tool is transferred to the orientation tool.
Plural instances may be provided for components, operations or structures described herein as a single instance. For example, while two sets of latch orientation housings are shown in
Use of the phrase “at least one of” preceding a list with the conjunction “and” should not be treated as an exclusive list and should not be construed as a list of categories with one item from each category, unless specifically stated otherwise. A clause that recites “at least one of A, B, and C” can be infringed with only one of the listed items, multiple of the listed items, and one or more of the items in the list and another item not listed.
Unless otherwise specified, any use of any form of the terms “connect,” “engage,” “couple,” “attach,” or any other term describing an interaction between elements is not meant to limit the interaction to direct interaction between the elements and may also include indirect interaction between the elements described. In the preceding discussion and in the claims, the description refers to up or down as relative directions and not absolute directions. The terms “up,” “upper,” “upward,” or “pick-up direction” describe a direction toward the surface of a wellbore regardless of the wellbore orientation. Similarly, the terms “down,” “lower,” “downward,” “downhole direction”, or “run-in direction” describe a direction toward the terminal end of a wellbore regardless of the wellbore orientation. Reference to in or out will be made for purposes of description with “in,” “inner,” or “inward” meaning toward the center or central axis of the wellbore, and with “out,” “outer,” or “outward” meaning toward the wellbore tubular and/or wall of the wellbore. Reference to “longitudinal,” “longitudinally,” or “axially” means a direction substantially aligned with the main axis of the wellbore and/or wellbore tubular. Reference to “radial” or “radially” means a direction substantially aligned with a line between the main axis of the wellbore and/or wellbore tubular and the wellbore wall that is substantially normal to the main axis of the wellbore and/or wellbore tubular, though the radial direction does not have to pass through the central axis of the wellbore and/or wellbore tubular. The term “circumferential latch keys” can mean both a set of continuous collets surrounding a cylinder or a set of distributed circumferential shapes that are rotationally symmetric. The various characteristics mentioned above, as well as other features and characteristics described in more detail above, will be readily apparent to those skilled in the art with the aid of this disclosure upon reading the following detailed description of the embodiments, and by referring to the accompanying drawings.
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Number | Date | Country | |
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Parent | 16465794 | US | |
Child | 17304817 | US |