During drilling operations, drilling mud may be pumped into a wellbore. The drilling mud may serve several purposes, including applying a pressure on the formation, which may reduce or prevent formation fluids from entering the wellbore during drilling. The formation fluids mixed with the drilling fluid can reach the surface, resulting in a risk of fire or explosion if hydrocarbons (liquid or gas) are contained in the formation fluid. To control this risk, pressure control devices are installed at the surface of a drilling, such as one or more blowout preventers (BOPs) that can be attached onto a wellhead above the wellbore. A rotating control device (RCD) is typically attached on the top of the BOPs to divert mud/fluid to, and circulate it through, a choke manifold to avoid the influx of fluid reaching a drilling rig floor (as well as allowing pressure management inside the wellbore). The RCD includes a bearing assembly used for purposes of controlling the pressure of fluid flow to the surface while drilling operations are conducted. The bearing assembly is typically raised by a top drive assembly and then inserted into a “bowl” of the RCD. The bearing assembly rotatably receives and seals a drill pipe during drilling operations through the wellhead. Thus, the bearing assembly acts as a seal and a bearing, as supported by the RCD.
After the bearing assembly is inserted into the bowl of the RCD, the RCD can be operated to “lock” a stationary housing of the bearing assembly to the RCD (while still allowing for the rotational components of the bearing assembly to rotate along with a rotating drill pipe). This “locking” function is typically performed with ram mechanisms coupled to the RCD housing and that are actuated to lock the bearing assembly to the RCD housing, and then actuated to unlock the bearing assembly from the RCD housing (such as when seals of the bearing assembly need to be replaced). Another type of locking mechanisms includes a clamp mechanism that is manually or hydraulically actuated to lock the bearing assembly to the RCD housing. Both the ram mechanisms and the clamp mechanism have various drawbacks. More specifically, the ram mechanism must have internal machine threads and a threaded rod, and a motor to rotate the threaded rod. The rod drives the ram into the bearing assembly to lock it. This is disadvantageous because the ram mechanism must be locked manually by an operator, which is dangerous and time consuming. The clamp mechanism is disadvantageous because it must be manually operated by an individual operator to lock the bearing assembly to the RCD housing, which is dangerous and time consuming.
Features and advantages of the invention will be apparent from the detailed description which follows, taken in conjunction with the accompanying drawings, which together illustrate, by way of example, features of the invention; and, wherein:
Reference will now be made to the exemplary embodiments illustrated, and specific language will be used herein to describe the same. It will nevertheless be understood that no limitation of the scope of the invention is thereby intended.
As used herein, the term “substantially” refers to the complete or nearly complete extent or degree of an action, characteristic, property, state, structure, item, or result. For example, an object that is “substantially” enclosed would mean that the object is either completely enclosed or nearly completely enclosed. The exact allowable degree of deviation from absolute completeness may in some cases depend on the specific context. However, generally speaking the nearness of completion will be so as to have the same overall result as if absolute and total completion were obtained. The use of “substantially” is equally applicable when used in a negative connotation to refer to the complete or near complete lack of an action, characteristic, property, state, structure, item, or result.
As used herein, “adjacent” refers to the proximity of two structures or elements. Particularly, elements that are identified as being “adjacent” may be either abutting or connected. Such elements may also be near or close to each other without necessarily contacting each other. The exact degree of proximity may in some cases depend on the specific context.
An initial overview of the inventive concepts are provided below and then specific examples are described in further detail later. This initial summary is intended to aid readers in understanding the examples more quickly, but is not intended to identify key features or essential features of the examples, nor is it intended to limit the scope of the claimed subject matter.
The present disclosure sets forth a rotating control device (RCD) for use on a drill rig, and particularly a locking block system of an RCD. The RCD comprises a housing (often referred to as or defining a bowl) operable with a blowout preventer, and a bearing assembly operable to be received in the housing, and operable to receive a pipe of a drill string. The locking block system of the RCD comprises a plurality of locking block assemblies supported by the housing. Each locking block assembly comprises a movable block movable between an unlocked position that unlocks the bearing assembly from the housing, and a locked position that automatically locks the bearing assembly to the housing.
In one example, each locking block assembly comprises: the movable block configured to interface with a perimeter channel of a stationary bearing housing of the bearing assembly when in the locked position; at least one elastic component situated between the housing and the movable block, and configured to automatically bias the movable block in the locked position; and a valve device coupled to the housing and movably interfaced with the movable block, wherein, upon supplying hydraulic fluid pressure via the valve device, the movable block moves to the unlocked position and the at least one elastic component compresses. And, upon removing hydraulic fluid pressure via the valve device, the at least one elastic component expands to automatically lock the movable block to the perimeter channel of the stationary bearing housing.
The present disclosure sets forth an RCD for use on a drill rig. The RCD comprises an RCD housing coupled to a blowout preventer; a bearing assembly received within the RCD housing and comprising a stationary bearing housing having a perimeter channel; and a plurality of locking block assemblies supported by the RCD housing. Each locking block assembly comprises a movable block automatically biased in a locked position to engage the perimeter channel of the stationary bearing housing to lock the bearing assembly to the RCD housing.
In one example, when the locking block assembly transitions from an unlocked position to the locked position, at least one elastic components bias the respective movable blocks toward the bearing assembly to facilitate lateral self-alignment of the bearing assembly relative to the RCD housing.
The present disclosure sets forth a locking block system for facilitating replacement of one or more sealing elements associated with an RCD. The system comprises an RCD comprising a RCD housing coupled to a blowout preventer, and a bearing assembly received within the RCD housing and configured to receive a pipe of a drill string of the oil rig. The bearing assembly comprises: a stationary bearing housing; a lower sealing element coupled to the stationary bearing housing, the lower sealing element sealingly engaged (i.e., engaged in a manner, such that a seal is formed) with the pipe; a upper sealing element housing coupled to an upper sealing element sleeve; an upper sealing element coupled to the upper sealing element sleeve, and the upper sealing element is sealingly engaged with the pipe. The system comprises a plurality of lower locking block assemblies supported by the RCD housing and operable between a locked position and an unlocked position, wherein, when in the locked position, the plurality of lower locking block assemblies lock the stationary bearing housing to the RCD housing, and, when in the unlocked position, the locking block assemblies unlock the stationary bearing housing from the RCD housing to facilitate replacement of the lower sealing element. The system further comprises a plurality of upper locking block assemblies supported by the upper sealing element housing and operable between a locked position and an unlocked position, wherein, when in the locked position, the plurality of upper locking block assemblies lock the upper sealing element sleeve to the upper sealing element housing, and, when in the unlocked position, the plurality of upper locking block assemblies unlock the upper sealing element sleeve from the upper sealing element housing to facilitate replacement of the upper sealing element.
The present disclosure sets forth a method for operating a locking block system of an RCD of a drill rig comprising identifying an RCD coupled to a blowout preventer of a drill rig. The RCD comprises an RCD housing operable with the blowout preventer and is configured to receive a bearing assembly that receives a pipe of a drill string. The RCD comprises a bearing assembly receivable into the RCD housing. The bearing assembly is operable to receive a pipe of a drill string of a drill rig. The RCD comprises a plurality of locking block assemblies supported by the RCD housing, where each locking block assembly has a movable block and at least one elastic component. The method comprises applying an actuation force to the movable blocks of the plurality of locking block assemblies to be in an unlocked position, wherein each moveable block is caused to be displaced in a direction so as to compress the respective at least one elastic component. The method comprises selectively maintaining the movable blocks in the unlocked position by maintaining application of the actuation force on the moveable blocks, and then inserting the bearing assembly into the RCD housing. The method comprises removing the actuation force, whereby the movable blocks transition from the unlocked position to a locked position, such that the moveable blocks interface with and engage the bearing assembly.
In one example, removing the actuation force comprises removing fluid pressure from the movable blocks via a valve device to allow the respective at least one elastic components to cause the respective movable blocks to automatically move to the locked position.
In one example, selectively maintaining the movable blocks in an unlocked position comprises supplying fluid pressure to each movable blocks via the respective valve devices.
To further describe the present technology, examples are now provided with reference to the figures.
With reference to
The housing 110 can comprise sub-housings 118a-c that each support respective lower locking block assemblies as part of a locking block system for the RCD 100 (see lower locking block assemblies 120a, 120b in
The bearing assembly 102 can comprise a stationary bearing housing 122 that rotatably supports a lower sealing element sleeve 124 via upper and lower bearing assemblies 126a and 126b (
A lower sealing assembly 128 can be attached to a lower end of the rotary casing 124 via fasteners 130. The lower sealing assembly 128 can comprise a lower plate lock device 132 and a lower sealing element 134 (e.g., rubber stripper/packer) removably coupled to the lower plate lock device 132. One example configuration of the lower sealing assembly 128 is further described in U.S. patent application Ser. No. 16/054,969, filed Aug. 3, 2018, which is incorporated by reference herein in its entirety. Those skilled in the art will recognize other ways for coupling the lower sealing element 134 to or about the bearing assembly 102.
The lower sealing element 134 can comprise an opening 136 sized to receive a pipe 108 (
In one example, as shown, the upper sealing assembly 109a can comprise a upper sealing element housing 138 coupled to an upper end of the lower sealing element sleeve 124 via fasteners 140. Note that the upper sealing assembly 109a is an optional assembly that can be coupled to the lower bearing assembly 109b; however, only the lower bearing assembly 109b may be utilized in some applications as desired. The upper sealing element housing 138 defines a bowl area 142, and supports a plurality of upper locking block assemblies 144a and 144b operable to lock and unlock an upper sealing element sleeve 146, via a perimeter channel 256 of the upper sealing element sleeve 146, from the upper sealing element housing 138, as further detailed below. An upper sealing assembly 148 can be coupled to a lower end of the upper sealing element sleeve 146 via fasteners 149. The upper sealing assembly 148 can comprise an upper plate lock device 150 and an upper sealing element 152 (e.g., a rubber stripper/packer) removably coupled to the upper plate lock device 150. The configuration of the upper sealing assembly 148 is further described in U.S. patent application Ser. No. 16/054,969, filed Aug. 3, 2018, which is incorporated by reference herein in its entirety. The upper sealing element 152 can comprise an opening 154 sized and configured to receive the pipe 108, wherein the upper sealing element 152 tightly grips and seals against the pipe 108 (
When the upper and lower sealing elements 152 and 134 wear down and need to be replaced (e.g., sometimes daily), the bearing assembly 102 can be removed from the RCD housing 110 when the lower locking block assemblies (e.g., lower locking block assemblies 120a-c) are in the unlocked position (discussed below). Once the bearing assembly 102 is removed, the lower sealing element 134 can be removed (via the lower plate lock device 128) and replaced with a new sealing element. Similarly, the upper sealing element sleeve 146 (and the attached upper sealing element 152) can be removed from the upper sealing element housing 138 upon moving the upper locking block assemblies 144a and 144b to the unlocked position, and the upper sealing element 152 replaced with a new sealing element.
With reference to
More specifically, and in one example, the stationary bearing housing 122 can comprises a perimeter or circumferential groove or channel 156 formed as an annular recess around the generally cylindrically-shaped stationary bearing housing 122 (see e.g.,
The lower locking block assemblies 120a-c can each comprise a housing support member 158a-c removably coupled to respective sub-housings 118a-c via fasteners (not shown), for instance (see e.g.,
With continued reference to
The term “block” can mean generally a block or cuboid shaped component, such as one having a rectangular cross-sectional area (along one or more planes). However, this is not intended to be limiting in any way to the shape or configuration of the movable component that can interface and engage with the stationary bearing housing 122. Thus, shapes other than “blocks” could be formed and achieve the same function and result, such as a spherically shaped movable component that interfaces with a corresponding spherical surface of the stationary bearing housing 122, for instance.
In one example, the locking block assembly 120a can comprise a pair of elastic components 170a and 170b configured to automatically bias (i.e., apply a force, such as a spring force, to and in the direction of) the movable block 162a in the locked position. More specifically, and with further reference to
Regarding transitioning or moving from the locked position (
The body section 182 of the valve device 174 can comprise a fluid port 186 and a first fluid conduit 188a in fluid communication with each other. The first fluid conduit 188a can be a linear fluid opening in fluid communication with second and third conduits 188b and 188c that each extends orthogonal from the first fluid conduit 188a, as formed through the head portion 178. The second and third conduits 188b and 188c are in fluid communication with a fluid pressure chamber 191 defined by the first opening 180a and the valve device 174. Thus, the head portion 178 is positioned slightly laterally offset from an end of the first opening 180a (
Accordingly, a fluid (hydraulic or pneumatic) system 194 (schematically shown) can be operatively coupled to the lower locking block assembly 120a, wherein the hydraulic system 194 can comprise a fluid line 196 in fluid communication with the fluid port 186. Thus, when the lower locking block assembly 120a is in the locked position of
As can be appreciated, such actuation force applied by the fluid system 194 to move the movable block 162a, for instance, to the unlocked position is greater than the spring force exerted by the elastic components 170a and 170b (that maintains the movable block 162a in the locked position). Due to this actuation force, the movable block 162a may effectively move to the unlocked position of
In this system, the movable block 162a can automatically transition from the unlocked position (
Advantageously, this system provides a fail-safe device to help prevent injury to operators working around the RCD 100 because the locking block assemblies 120a-c are caused to be in a locked position by default, and to automatically self-lock to the bearing assembly 102 upon removing fluid pressure from the movable blocks 120a-c. For example, if fluid pressure is lost due to failure of the hydraulic system for some reason, the locking block assemblies 120a-c will automatically move to the locked position via the aforementioned stored spring force. This can ensure that the bearing assembly 102 is not blown out upwardly by wellbore fluid pressure during drilling in instances where the system fails or loses pressure, which can potentially be catastrophic to the system and human operators. Moreover, there is no requirement for a human operator to manually interact with or engage the bearing assembly 102 to lock it to the RCD housing 110, which improves safety and efficiency of the system because it prevents possible injury while automating the locking function, in contrast with prior systems that are manually operated (e.g., with rams, clamps, etc.), and/or that require the system to perform an active actuation function to lock the bearing assembly.
Such “automatic” locking movement to the locked position also assists to properly align the bearing assembly 102 with the RCD housing 110, which is important for proper downhole drilling and to prolong the life of the bearing assembly 102. This is because, with prior current or existing technologies that rely on active actuation to lock a bearing assembly to an RCD housing (e.g., ram locks controlled by electric or hydraulic motors), precisely controlling the travel and position of such ram locks relative to each other is difficult and problematic because, in many instances, one of the ram locks may move too quickly (and/or its starting position may be unknown), thereby contacting the bearing assembly before the other ram locks happen to contact the bearing assembly. This often misaligns the bearing assembly relative to the RCD housing (i.e., the central axis of the wellhead and RCD housing may be not-collinear with the rotational axis of the bearing assembly). This can cause the bearing assembly to rotate off-axis relative to the central axis of the RCD housing, which can cause the bearings and sealing elements to wear down more rapidly. This can also damage components of the overall system in instances where the ram locks are in different lateral positions around the bearing assembly, or even cause mud/debris to enter into and through the bearing assembly.
However, with the present technology disclosed herein, the (expanding) the locking block assemblies 120a-c, including the respective moveable blocks 162a-c and the elastic components (e.g., 170a and 170b) associated with each movable block 162a-c, when transitioning to the locked position, are configured to and tend to compensate for possible misalignment. For example, if the movable block 162a first contacts the stationary bearing assembly 122 before the other movable blocks 162b and 162c happen to contact the stationary bearing assembly 122, the elastic components 170a and 170b of the movable block 162a may slightly compress to accommodate for the pressure applied by the other movable blocks 162b and/or 162c when they (eventually) contact the stationary bearing housing 122. Thus, the bearing assembly 102 tends to float about the housing 110 when the movable blocks 162a-c transition from the unlocked position to the locked position, so that the bearing assembly 102 is allowed to self-align with the RCD housing 110 in lateral directions. The strategic positioning of the locking block assemblies 120a-c relative to one another can also assist in helping the system to self-align (e.g., the locking block assemblies being spaced a strategic distance from one another). In this manner, the elastic component(s) of each of the movable blocks 162a-c may be identical or substantially the same (e.g., have the same spring constant, material, pre-load position, length, and other properties). Therefore, an equal or substantially equal amount of biasing spring force may be exerted by each of the lower locking block assemblies 120a-c. This can help to ensure that there is an equal amount of force being exerted against and around the bearing assembly 102 to maintain it in the locked position. However, some differences in the amounts of applied force from each of the locking block assemblies 120a-c can be possible and accounted for, such as may be the case if the bearing assembly 102 is not precisely aligned with the RCD housing 110.
This “floating” functionality can also be advantageous during drilling operations and while components of the bearing assembly 102 rotate. For example, if the bearing assembly 102 happens to slightly move laterally relative to the housing 110 along the x axis and/or y axis, the elastic components of one or more locking block assemblies can slightly compress (or expand as the case may be) due to said slight lateral movement of the bearing assembly 102. This assists to continuously align the bearing assembly 102, in real-time during drilling, relative to the housing 110 to facilitate lateral movement of the bearing assembly 102 in at least one translational degree of freedom (x and/or y translational axes). Therefore, the bearing assembly 102 can be maintained in a constant aligned position relative to the housing 110. This can further prolong the life of components of the system, such as the upper and lower sealing elements 152 and 134, and the tapered bearings 126a and 126b, because an axis of rotation Y of the bearing assembly 102 can be substantially or completely aligned with a vertical centerline C of the RCD housing 110.
As can be appreciated by the view of
With further reference to
Similarly, the housing 110 itself can also comprise a transition surface, such as a chamfer (e.g., chamber 200a) formed annularly adjacent a shoulder portion 202 of the housing 110, as shown in
These self-alignment features can be advantageous in the face of several potential operational situations. For example, the housing 110 may not always be properly vertically disposed as extending from the borehole (e.g., relative to Earth and gravity). Moreover, the bearing assembly 102 may not always be properly aligned with the housing 110 while the bearing assembly 102 is being inserted into the housing 110 via a top drive assembly. Still further, a large amount of spring force can be exerting against each movable block (e.g., 500 pounds or more for each elastic component), causing the movable blocks to bind-up or jam against the stationary bearing housing 122 when moving to the locked position. Thus, to account for these considerations, and to properly align and lock the bearing assembly 102 to the housing 110, the chamfers 200a and 200b are formed, as described above, to help self-align the bearing assembly 102 to the housing 110 when being inserted into the housing 110. Similarly, the chamfers 198a and 198b are formed, as described above, to vertically guide and self-align the movable blocks 162a-c when transitioning from the unlocked position to the locked position to the stationary bearing housing 122, in case the bearing assembly 102 is not properly vertically aligned with the housing 110.
On either side of chamfer 200a of the housing 110, a pair of seals 206a and 206b may be disposed to prevent mud and other debris from entering areas of the bearing assembly 102.
With further reference to
As discussed above, as the pipe 108 is rotated, the rotary bearing casing 124, the sealing element 134, and the upper sealing assembly 109a concurrently rotate about the axis of rotation Y. Such rotational movement generates inertia, which exerts a rotational inertia force to the stationary bearing housing 122 via the tapered bearing assemblies 126a and 126b. Such inertial force is undesirable because the stationary bearing housing 122 must not rotate and should be locked to the RCD housing 110 to prevent wear or damage on components associated with the RCD 100 and its bearing assembly 102.
Therefore, in one example (e.g., as shown in
More specifically, each movable block 162a-c can support respective anti-rotation devices 212a-c about insert portions 214a-c of each movable block 162a-c, as shown in
Accordingly, each movable anti-rotation device 212a-c moves along with the respective movable blocks 162a-c between the locked and unlocked positions, as detailed above regarding
Each movable anti-rotation device 212a-c and the locking ring 210 can define a frictional anti-rotation locking system. Specifically, in this example the locking ring 210 includes a first frictional surface 221 (i.e., an outer perimeter surface), and each movable anti-rotation device 212a-c includes a frictional surface 219a-c (i.e., an outer surface facing the first frictional surface 221)(see
In one example, the frictional surfaces 219a-c can each comprises a brake pad surface, such as those formed of synthetic composites, semi-metallic materials, metallic materials, ceramic materials and others as will be apparent to those skilled in the art. The second frictional surfaces 219a-c can be configure to comprise a suitable coefficient of friction (e.g., from 0.35 to 0.42 (or it can vary from such range)). Accordingly, the locking ring 210 can be comprised of composite, ceramic, metal, or other suitable material(s), the locking ring 210 also comprising a thin layer or surface of similar brake pad material, such that the first frictional surface 221 operates or functions to provide a suitable coefficient of friction to prevent relative rotation between the stationary bearing housing 122 and the RCD housing 110 upon interfacing and interacting with the frictional surfaces 219a-c when in the locked position. In this manner, a collective frictional force between the movable anti-rotation devices 212a-c and the locking ring 210 can be configured to be greater than an inertia force exerted on the stationary bearing housing 122 upon rotation of the pipe 108 and the rotating components of the bearing assembly 102. Therefore, the stationary bearing housing 122 is restricted from rotation relative to the RCD housing 110 upon moving the movable blocks 162a-c, and the anti-rotation devices 212a-b, to the locked position, such that a collective frictional force is generated between the locking ring 210 and the movable anti-rotation devices 212a-c.
In one example, the movable blocks 162a-c can be moved upon the release of potential energy by their respective elastic components (e.g., elastic components 170a and 170b), as discussed above. The spring force exerted by each elastic component can be about as needed. For example, in some cases, the elastic component(s) can be configured to exert between 400 and 600 pounds, although this is not intended to be limiting in any way. This spring force biases the respective movable blocks 162a-c inwardly toward the locking ring 210 until each movable anti-rotation device 212a-c contacts and frictionally engages with the locking ring 210, as described above. Then, upon supplying fluid pressure to the movable blocks 162a-c, the anti-rotation devices 212a-c are disengaged from or moved away from the locking ring 210, thereby removing the friction force. Some examples of means of actuation of the movable blocks 162a-c is described above.
Alternatively, an actuation system 223 can be coupled to all of the movable blocks 162a-c to actively actuate the movable blocks 162a-c between unlocked and locked positions along their respective axes of translation X1, X2, and X3. The actuation system 223 can comprise a hydraulic actuator, an electric actuator, a pneumatic actuator, and/or other actuator configured to effectuate translational movement of the movable blocks 162a-c along their respective axes of translation between the locked and unlocked positions. In other words, the elastic components and valve devices described above (with reference to
Regardless of the means of actuating the movable blocks 162a-c, the stationary bearing housing 122 can be locked to the RCD housing 110 independent of the rotational position of the stationary bearing housing 122 relative to the RCD housing 110. That is, when the bearing assembly 102 is inserted into the RCD housing 110, the rotational position of the stationary bearing housing 122 may be unknown and/or dynamically changing because the top drive assembly merely picks up and inserts the bearing assembly 102 into the RCD housing 110 without regard to, or exact control over, the rotational position of the stationary bearing housing 122. However, with the present example of the frictional anti-rotation locking system, the rotational position of the stationary bearing housing 122 is less relevant because the entire outer perimeter surface of the locking ring 210 is a frictional surface (i.e., the first frictional surface) that can be engaged by the movable anti-rotation devices 212a-c when moved to the locked position. Thus, the rotational position of the stationary bearing housing 122 is independent of the position of the movable anti-rotation devices 212a-c (and the housing 110) because the movable anti-rotation devices 212a-c can contact any surface portion of the first frictional surface 221 of the locking ring 210 (collectively and automatically) despite the position of the stationary bearing housing 122 and the attached locking ring 210. Other systems require human interaction with the bearing assembly (i.e., grabbing/rotating) to clock or position a bearing assembly to a desired position before locking said bearing assembly to an RCD housing, which is time consuming and dangerous to the operators because their hands are prone to injury around the various moving parts associated with the RCD, its bearing assembly, and the top drive.
With continued reference to
More specifically, a plurality of locking block assemblies 320a-c (e.g., which are similar to locking block assemblies 120a-c discussed above) can comprise respective movable blocks 362a-c (e.g., similar to movable blocks 162a-c discussed above) that support respective movable anti-rotation devices 312a-c about insert portions of each movable block 362a-c (e.g., see insert portion 314a of movable block 162a). The insert portions can be formed about a central outer portion of the respective movable blocks 362a-c, and can be sized to receive and retain respective movable anti-rotation devices 312a-c.
Each movable anti-rotation device 312a-c moves along with the respective movable block 362a-c between the locked and unlocked positions, as detailed above in one example regarding movable blocks 162a-c. As shown in
Each movable anti-rotation device 312a-c and the locking ring 310 can define a geared anti-rotation locking system. Specifically, the locking ring 310 can comprise geared teeth 321, and each movable anti-rotation device 312a-c can comprise respective locking geared teeth 319a-c formed therein and configured to engage with at least some of the geared teeth 321 of the locking ring 310 (such as with a gear/pinion interface). As shown, the individual teeth of the geared teeth 321 can be formed adjacent each other and around the entire perimeter of the locking ring 310. All the teeth associated with the geared anti-rotation locking system can comprise a suitable geared tooth geometry or nomenclature, such as spur gear teeth, Wildhaber-Novikov teeth, and other suitable geared configurations.
In this example, the teeth 319a-c of the anti-rotation devices 312a-c are configured to interface with the geared teeth 321 of the locking ring 310, when in the locked position (
In one example, the movable blocks 362a-c can be moved upon the release of potential energy by the elastic components 170a and 170b, as discussed above. Such spring force biases the respective movable blocks 362a-c inwardly toward the locking ring 310 until each movable anti-rotation device 312a-c contacts and engages with the locking ring 310. Then, upon supplying fluid pressure to the movable blocks 362a-c (e.g., as described above regarding 162a-c), the anti-rotation devices 312a-c are disengaged from or are moved away from the locking ring 310, thereby removing the locking force. Alternatively, an actuation system 323 can be coupled to each movable block 362a-c to actively actuate the movable blocks 362a-c between unlocked and locked positions, such as described regarding
Advantageously, the stationary bearing housing 322 can be locked to the RCD housing 110 independent of the rotational position of the stationary bearing housing 122 relative to the RCD housing 110. That is, when the bearing assembly 102 is inserted into the RCD housing 110, the rotational position of the stationary bearing housing 122 may be unknown or variable because the top drive assembly merely picks up and inserts the bearing assembly 102 into the RCD housing 110 without regard to the rotational position of the stationary bearing housing 122. However, with the present example of the geared anti-rotation locking system, the rotational position of the stationary bearing housing 122 is less relevant because the entire perimeter of the locking ring 310 comprises geared teeth configured to engage with any of the teeth of each of the movable anti-rotation devices 312a-c when moved to the locked position. Thus, the rotational position of the stationary bearing housing 122 is independent of the position of the movable anti-rotation devices 312a-c and the housing 110 because the movable anti-rotation devices 312a-c can contact any portion of the locking ring 310 (collectively and automatically), despite the position of the stationary bearing housing 122 and the attached locking ring 310.
With continued reference to
More specifically, a plurality of locking block assemblies 420a-c (e.g., which are similar to locking block assemblies 120a-c discussed above) can comprise respective movable blocks 462a-c (e.g., similar to movable blocks 162a-c, also discussed above) that support respective movable anti-rotation devices 412a-c about insert portions of each movable block 462a-c (e.g., see insert portion 414a of movable block 162a). The insert portions 414a-c can be formed about a central outer portion of the respective movable blocks 462a-c, and can be sized to receive and retain respective movable anti-rotation devices 412a-c.
Each movable anti-rotation device 412a-c moves along with the supporting respective movable block 462a-c between the locked and unlocked positions, as detailed above in one example regarding movable blocks 162a-c. As shown in
Each movable anti-rotation device 412a-c and the locking ring 410 can define a pinned anti-rotation locking system. Specifically, the locking ring 410 includes perimeter openings 421, and each movable anti-rotation device 412a-c includes a locking pin 419a-c sized to interface or engage with one opening of the perimeter openings 421 of the locking ring 410 when transitioning to the locked position. Each locking pin 419a-c can be a cylindrically shaped protrusion extending toward the locking ring 410, and each of the perimeter openings 421 can be a bore formed radially through and around the entire perimeter of the locking ring 410.
The perimeter openings 421 can be sized slightly larger than the locking pins 419a-c to facilitate proper engagement, as shown in
In one example, the movable blocks 462a-c can be moved upon the release of potential energy by the elastic components 170a and 170b, as discussed above. Such spring force biases the respective movable blocks 462a-c inwardly toward the locking ring 410 until each movable anti-rotation device 412a-c engages with the locking ring 410. Then, upon supplying fluid pressure to the movable blocks 462a-c, the anti-rotation devices 412a-c are moved away from the locking ring 410, thereby removing any locking force. Alternatively, an actuation system 423 can be coupled to each movable block 462a-c to actively actuate the movable blocks 462a-c between unlocked and locked positions, such as described regarding
Advantageously, the stationary bearing housing 122 can be locked to the housing 110 independent of the rotational position of the stationary bearing housing 122 relative to the housing 110. That is, when the bearing assembly 102 is inserted into the housing 110, the rotational position of the stationary bearing housing 122 may be unknown or dynamically changing because the top drive assembly merely picks up and inserts the bearing assembly 102 into the housing 110 without regard to the rotational position of the stationary bearing housing 122. However, with the present example of the pinned anti-rotation locking system, the rotational position of the stationary bearing housing 122 is less relevant because the entire perimeter of the outer surface of the locking ring 410 comprises numerous openings each configured to be engaged by respective locking pins 419a-c of the movable anti-rotation devices 412a-c when moved to the locked position.
Thus, the rotational position of the stationary bearing housing 122 is substantially independent of the position of the movable anti-rotation devices 412a-c because their locking pins 419a-c can engage with any opening of the locking ring 410 (collectively and automatically), despite the position of the stationary bearing housing 122 and the attached locking ring 410. This is because the pipe 108 may be rotating the bearing assembly 102 as it is being inserted into the housing 110, so that the locking ring 410 and its perimeter openings 421 would be slowly rotating as the movable blocks 462a-c are moving to the locked position. In this manner, the pins 419a-c will eventually interface with and engage an opening of the perimeter openings 421.
In an alternative example, the perimeter openings described regarding
Reference was made to the examples illustrated in the drawings and specific language was used herein to describe the same. It will nevertheless be understood that no limitation of the scope of the technology is thereby intended. Alterations and further modifications of the features illustrated herein and additional applications of the examples as illustrated herein are to be considered within the scope of the description.
Furthermore, the described features, structures, or characteristics may be combined in any suitable manner in one or more examples. In the preceding description, numerous specific details were provided, such as examples of various configurations to provide a thorough understanding of examples of the described technology. It will be recognized, however, that the technology may be practiced without one or more of the specific details, or with other methods, components, devices, etc. In other instances, well-known structures or operations are not shown or described in detail to avoid obscuring aspects of the technology.
Although the subject matter has been described in language specific to structural features and/or operations, it is to be understood that the subject matter defined in the appended claims is not necessarily limited to the specific features and operations described above. Rather, the specific features and acts described above are disclosed as example forms of implementing the claims. Numerous modifications and alternative arrangements may be devised without departing from the spirit and scope of the described technology.
Number | Name | Date | Kind |
---|---|---|---|
3621912 | Wooddy, Jr. | Nov 1971 | A |
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