The present disclosure generally relates to oilfield equipment and, in particular, to downhole tools, drilling and related systems for steering a drill bit. More particularly still, the present disclosure relates to methods and systems for preventing overextension of the steering pads of a downhole tool.
Drilling wellbores in a subterranean formation usually requires controlling a trajectory of the drill bit as the wellbore is extended through the formation. The trajectory control can be used to steer the drill bit to drill vertical, inclined, horizontal, and lateral portions of a wellbore. In general the trajectory control can direct the drill bit into and/or through production zones to facilitate production of formation fluids, direct the drill bit to drill a portion of a wellbore that is parallel to another wellbore for treatment or production assist, direct the drill bit to intersect an existing wellbore, as well as many other wellbore configurations.
Therefore, it will be readily appreciated that improvements in the arts of preventing against overextension of the steering pads, so as to prevent the steering pads from becoming loose or completely coming apart during drilling operations, are continually needed.
The following figures are included to illustrate certain aspects of the present disclosure, and should not be viewed as exclusive embodiments. The subject matter disclosed is capable of considerable modifications, alterations, combinations, and equivalents in form and function, without departing from the scope of this disclosure.
The disclosure may repeat reference numerals and/or letters in the various examples or Figures. This repetition is for the purpose of simplicity and clarity and does not in itself dictate a relationship between the some embodiments and/or configurations discussed.
The present disclosure further relates to methods and systems for preventing overextension of steering pads of a rotary steerable tool during drilling operations downhole. Generally, the present disclosure describes a rotary steerable tool for steering a drill string including a steering head that can include a stop mechanism for preventing overextension of the steering pads. This can be achieved by restricting a rotational motion of the steering about a pivot axis of the steering pad. It is advantageous to restrict rotation of the steering pads about the pivot axis to prevent the steering pads from pivoting too far past the fully extended position to a point where the piston is displaced out of the piston bore. The present disclosure provides systems and methods for restricting rotation of the steering pads, as discussed in further detail below.
In order to prevent the steering pads from extending to the point that the piston becomes displaced or separated from the piston liner, an extension-limiting mechanism can be provided which acts as a stop to restrict rotation of the steering pads past a desired point. The extension-limiting mechanism can prevent or minimize loss of various components of the steering head downhole, which may not otherwise be retrievable.
According to some embodiments of the disclosure, the pad pusher includes first and second motion-limiting protrusions extending laterally from side faces of the steering pad. The steering pad may be rotationally coupled to a housing about a pivot axis of the steering pad. The housing may have a retaining recess extending through each of an uphole and a downhole side thereof. In some embodiments, each retaining recess extends partially through a cross-section of the housing at the respective uphole and downhole sides. In other embodiments, each retaining recess extends all the way through a cross-section of the housing at the respective uphole and downhole sides. The retaining recesses may be disposed at a position aligned with the respective first and second motion-limiting protrusions to receive the respective first and second motion-limiting protrusions therein. When the piston is actuated, a corresponding force is transferred to the steering pad. In some embodiments the steering pad is integrally formed with the piston as a single, continuous body or material. In other embodiments, the piston is otherwise coupled to steering pad. Thus the steering pad and the piston can move together along the same curved path. Motion of the steering pad and the piston, i.e., the pad pusher, causes a corresponding motion of the first and second motion-limiting protrusions within the respective retaining recesses. Thus, rotation of the first and second motion-limiting protrusions is limited to a cross sectional area of the retaining recesses. Accordingly, rotation of the steering pads, which may be integrally formed with the first and second motion-limiting protrusions, is restricted to the extent the first and second motion-limiting protrusions rotate in the retaining recesses. As such, some embodiments of the present disclosure advantageously provide methods and apparatus for preventing overextension of the steering pads by limiting rotation of the pads about the pivot axis.
At the surface location 16, the drilling rig 22 can be provided to facilitate drilling the wellbore 12. The drilling rig 22 can include a turntable 26 that rotates the tubing string 30 and the drill bit 102 together about the longitudinal axis X1. The turntable 26 can be selectively driven by an engine 27, and selectively locked to prohibit rotation of the tubing string 30. A hoisting device 28 and swivel 34 can be used to manipulate the tubing string 30 into and out of the wellbore 12. To rotate the drill bit 102 with the tubing string 30, the turntable 26 can rotate the tubing string 30, and mud can be circulated downhole by mud pump 23. The mud may be a calcium chloride brine mud, for example, which can be pumped through the tubing string 30 and passed through the downhole tool 100. In some embodiments, the downhole tool 100 can include a steering head, and a rotary valve that selectively applies pressure to at least one output flow path to hydraulically actuate the steering head. Additionally, the mud, if used above the rotary steerable tool and drill bit, can be pumped through a mud motor (not expressly illustrated in
As depicted, the steering head 218 is configured with a channel or bore 226 in which the piston 224 reciprocates upon being hydraulically or otherwise actuated. In some embodiments, the piston channel or bore 226 may be a linear channel or bore. In yet other embodiments, the piston channel or bore 226 in which the piston 224 reciprocates may be a curved channel or bore.
As the mud flows through the central bore 212, the mud can flow through a turbine 250 and past an electric generator, steering controller and motor assembly 260 used to control the angular position of the rotary valve 230. In the depicted example, mudflow 203 can pass through a filter screen 280 prior to passing through the rotary valve 230 and the flow manifold 240. The filter screen 280 can include apertures or openings sized to allow the flow of mud while preventing debris from passing through the flow manifold 240 and to components downstream of the flow manifold 240 to prevent obstruction and damage to the downstream components. The filter screen 280 can be formed from a metallic or ceramic perforated cylinder or mesh or any other suitable filter material.
In the depicted example, the rotary valve 230 and the flow manifold 240 regulate or control the flow of the mud there through to control the extension of the steering pads 220. In some embodiments, the rotation of the rotary valve 230 abutted against the flow manifold 240 controls the flow of mud through the flow manifold 240. The rotary valve 230 is rotated by a motor 264 within an electric generator, steering controller and electric motor assembly 260.
In the depicted example, as mud flow is permitted by the rotary valve 230, the mud flow can continue in a piston flow channel 242 of the flow manifold 240. In some embodiments, a piston flow channel 242 can pass through the flow manifold 240 and the tool body 210 to provide mud flow to the piston channel or bore 226. In the depicted example, the tool body includes one piston bore 226. However, as shall be illustrated and described in the various embodiments of the present disclosure, the tool body 210 can include one or more piston bores 226 formed in the tool body 210. In some embodiments, the piston bores 226 are disposed within a pad retention housing 221 formed within the tool body 210. In the depicted example, mud flow from the piston flow channel 242 is received by the piston bore 226 and the piston seals 228 to actuate and extend the piston 224. As illustrated, the steering pad 220 is integrally formed with the piston 224. However, as previously discussed, the steering pad 220 and the piston 224 may be separately formed and otherwise coupled. As described herein, the combination of the steering pad 220 and the piston 224, whether being formed as separate parts that are coupled together, or being formed as a part of a single, continuous body, shall be referred to as a pad pusher 223. The pad pusher 223 may be actuated by the mud flow provided through the piston flow channel 242, to extend the steering pad 220 radially outward against the wall of the wellbore 12.
Pressure against the piston 224 can be relieved by a relief flow channel 222 formed through the pad pusher 223. Mud flow can pass through the relief channel 222 to allow for maintaining or reducing pressure upon the piston 224 to facilitate the retraction of the piston 224 when the rotary valve 230 has closed mud flow to that piston.
In some embodiments, the mud flow can bypass the filter screen 280 and the flow manifold 240 to continue through the central bore 212 as a bypass flow 214. The bypass flow 214 can continue through the downhole end 204 of the drill string steering system 200 and can be directed to the bit nozzles 113 of the drill bit 102 to be circulated into an annulus of the wellbore 12.
In the depicted example, the motor 264 is an electrical motor that can be controlled to rotate the rotary valve 230 as desired to provide a desired drilling vector. In the depicted example, the motor 264 is contained within a motor housing 262 and rotates the rotary valve 230 via a motor shaft 270. In some embodiments, the motor 264 maintains the rotary valve 230 in a geostationary position as needed.
In the depicted example, components of the electric generator, steering controller and electric motor assembly 260 can be disposed, surrounded, bathed, lubricated, or otherwise exposed to a lubricant 265 within the motor housing 262 while many of the controller electronic components are protected in a pressure barrier cavity (not shown). In some embodiments the lubricant 265 is oil that is isolated from the mud within the wellbore. In the depicted example, the pressure of the lubricant 265 can be balanced with the downhole pressure of the mud. In some embodiments, a compensation piston 266 can pressurize the lubricant 265 to the same pressure as the surround mud without allowing fluid communication or mixing of the mud and the lubricant 265. In some embodiments, a biasing spring 268 can act upon the compensation piston 266 to further provide additional pressure to the lubricant 265 within the motor housing 262 relative to the pressure of the mud. The biasing spring 268 can impart around 25 psi of additional pressure, over the mud pressure, to the lubricant 265 within the motor housing 262. In some embodiments, electrical energy for the motor 264 is generated by mud flow passing through the turbine 250. In some embodiments, the turbine 250 can rotate about a turbine shaft 252 and power an electric generator.
In the depicted embodiments, the steering pad 220 and the piston 224 are integrally formed. However, as previously discussed, the steering pad 220 and the piston 224 may be separately formed and otherwise coupled. The term “integrally formed” can refer to a configuration in which the steering pad 220 and the piston 224 are formed as a single, continuous body or material. Thus, the steering pad 220 and the piston 224 move together along the same path. In some embodiments the path is a curved path which is defined by a curved piston liner defining the piston bore 226. In other embodiments, the piston channel or bore 226 may be a linear channel or bore. Thus, as depicted in
In the example illustrated in
In the depicted embodiments, the pad pusher motion restrictor 408 includes a first motion restrictor 408A at an uphole side, and a second motion restrictor 408B at a downhole side of the pad pusher 223. The housing motion restrictor 410 similarly includes a first motion restrictor 410A at an uphole side 210A, and a second motion restrictor 410B at a downhole side 210B of the housing 210. Thus, the first motion restrictor 408A of the pad pusher 223 may engage the first motion restrictor 410A of the housing 210, and the second motion restrictor 408B of the pad pusher may engage the second motion restrictor 410B of the second housing to restrict the motion of the steering pad 220 relative to the housing 221.
The first motion restrictor 408A of the pad pusher 223 may either be a first motion-limiting protrusion or a first retaining recess. Accordingly, the first motion restrictor 410A of the housing may either be a first retaining recess corresponding to the first motion-limiting protrusion of the pad pusher 223, or a first motion-limiting protrusion corresponding to the first retaining recess of the pad pusher 223. Similarly, the second motion restrictor 408B of the pad pusher 223 may either be a second motion-limiting protrusion or a second retaining recess. Accordingly, the second motion restrictor 410B of the housing 221 may either be a second retaining recess corresponding to the second motion-limiting protrusion of the pad pusher 223, or a second motion-limiting protrusion corresponding to the second retaining recess of the pad pusher 223. In some embodiments, the first and second motion restrictors of the housing may be first and second motion-limiting protrusions respectively, extending laterally from the respective uphole and downhole sides 221A and 221B of the housing 221. Accordingly, the first and second motion restrictors of the pad pusher 223 may be first and second retaining recesses extending laterally through the respective uphole and downhole sides 221A and 221B of the housing 221. Thus, the first and second retaining recesses are configured to receive the respective first and second motion-limiting protrusions therein.
In other embodiments, as depicted in
In the illustrated embodiments, cross-section of each of the first and second motion-limiting protrusions 408A, and 408B tapers in size along a plane orthogonal to an uphole-downhole direction of the steering pad 220. In particular, as illustrated for example, in
As illustrated in
As illustrated, for example in
For example, in some embodiments, each of the first and second recesses retaining recesses 410A and 410B may have a shape corresponding to a profile, full or partial, such as a top or bottom, of the respective first and second motion-limiting protrusions 408A and 408B. In other embodiments, the first and second recesses retaining recesses 410A and 410B may have a shape larger in cross-sectional profile than that of the corresponding first and second motion-limiting protrusions 408A and 408B. This would allow the first and second motion-limiting protrusions 408A and 408B to rotate therein. As shall be described below in further detail, shapes or profiles of the first and second recesses retaining recesses 410A and 410B may be designed so as to restrict motion of the steering pad relative to the housing 221. Thus, motion of the steering pad relative to the housing 221 may be restricted by each of the first and second motion-limiting protrusions 408A and 408B contacting the housing 221.
Operation of the steering pad overextension prevention mechanism of some embodiments of the present disclosure will now be described below in further detail.
In operation, the pad pusher 223 may be actuated by applying of hydraulic fluid (e.g., mud flow described above with respect to
Advantageously, various embodiments described herein can prevent the steering pad from rotating further than intended for the desired steering capability. Further, due to the capability of restricting rotation of the steering pad, the aforementioned configuration provides the advantage of preventing or minimizing the risk of the piston becoming displaced from the piston liner and piston bore. As a result, the piston may be prevented from becoming stuck after being displaced from the piston liner. Since the piston may be prevented from being removed from the liner, the chances of debris entering the liner and impeding steering control are minimized. The some embodiments described herein thus protect the steering head from additional damage.
Furthermore, by integrating the overextension prevention into the geometry of the steering pad and pad retention housings, it is possible to advantageously simplify the tool design by eliminating the need for additional stops in the steering head. This results in a more economical and more easily produced design. Additionally, the operating life of the tool is extended, for example, by virtue of not needing to provide additional stops which would potentially be subject to wear and breakage. Since the pad stops are provided in a same plane as the forces being applied to the pad pusher, the positioning of the pad stops (retaining recesses and limiting protrusions) provides better mechanical advantage over the forces the pad stops are counteracting. The stop distance can be changed prior to being run into the hole to select a desired minimum or maximum extension of the pad pusher using either different h sized limiting protrusions 408A and 408B or different positioned edges such as 422 or other ways to adjust the allowable pivot distance of the steering pad. In such instances it may be desirable to limit the allowable extension such that the pads do not extend beyond the diameter of the pervious casing or liner inner diameter for the interval being drilled so as to avoid the risk of the steering pad from getting caught on the bottom of the casing or liner when pulling the tool out of the hole or other potential obstructions. Hence the allowable swing or pivot range of steering pad may be selectable.
Various examples of aspects of the disclosure are described as numbered clauses (1, 2, 3, etc.) for convenience. These are provided as examples and do not limit the subject technology. Identification of the figures and reference numbers are provided below merely as examples for illustrative purposes, and the clauses are not limited by those identifications.
Clause 1: A steering head for steering a drill string, the steering head comprising: a pad pusher including a steering pad and a piston integrally formed, the steering pad having a pivot axis, and being rotatable about the pivot axis between retracted and extended positions, the pad pusher further including a motion restrictor to restrict rotation about the pivot axis; and a housing having a motion restrictor disposed at a position corresponding to the pad pusher motion restrictor, wherein the pad pusher motion restrictor is engageable with the housing motion restrictor to restrict motion of the steering pad relative to the housing.
Clause 2: The steering head of claim 1, wherein: the pad pusher motion restrictor comprises a first motion restrictor at an uphole side thereof, and a second motion restrictor at a downhole side thereof; the housing motion restrictor comprises a first motion restrictor at an uphole side thereof, and a second motion restrictor at a downhole side thereof; and the first motion restrictor of the pad pusher engages the first motion restrictor of the housing, and the second motion restrictor of the pad pusher engages the second motion restrictor of the second housing to restrict the motion of the steering pad relative to the housing.
Clause 3: The steering head of claim 2, wherein: the first motion restrictor of the pad pusher comprises one of a first motion-limiting protrusion or a first retaining recess, and the first motion restrictor of the housing comprises a remaining one of the first motion-limiting protrusion or the first retaining recess; and the second motion restrictor of the pad pusher comprises one of a second motion-limiting protrusion or a second retaining recess, and the second motion restrictor of the housing comprises a remaining one of the second motion-limiting protrusion or the second retaining recess;
Clause 4: The steering head of claim 1, wherein the first and second motion restrictors of the pad pusher comprise first and second motion-limiting protrusions extending laterally from the respective uphole and downhole sides; and the first and second motion restrictors of the housing comprise first and second retaining recesses respectively, configured to receive the respective first and second motion-limiting protrusions therein.
Clause 5: The steering head of Clause 4, wherein each of the first and second retaining recesses comprises a trapezoidal cross-section, with top and bottom edges thereof being parallel.
Clause 6: The steering head of Clause 5, wherein the trapezoidal shaped cross-section comprises a cross-section having a rectangular shape.
Clause 7: The steering head of Clause 5, wherein the trapezoidal cross-section comprises a cross-section having a square shape.
Clause 8: The steering head of Clause 4, wherein a cross-section of each of the first and second motion-limiting protrusions tapers in size along a plane orthogonal to an uphole-downhole direction of the steering pad.
Clause 9: The steering head of Clause 8, wherein the size comprises a height of the cross-section of each of the first and second motion-limiting protrusions.
Clause 10: The steering head of Clause 4, wherein each of the first and second motion-limiting protrusions comprise a first edge, a second edge parallel to the first edge, and a third angularly oriented edge coupled to at least one of the first and second edges.
Clause 11: The steering head of Clause 10, wherein in a fully retracted position of the pad pusher, the third edge is positioned parallel to a bottom edge of the respective first and second retaining recesses.
Clause 12: The steering head of Clause 10, wherein in a fully extended position of the pad pusher, the first edge abuts a top edge of the respective first and second retaining recesses to restrict further rotation of the pad pusher about the pivot axis in a first direction.
Clause 13: The steering head of Clause 12, wherein in the fully extended position of the pad pusher, the first edge extends parallel to the top edge of the respective first and second retaining recesses to restrict further rotation of the pad pusher about the pivot axis in a first direction.
Clause 14: The steering head of Clause 4, wherein the steering pad has a semi-circular cross-sectional profile and the pad pusher is attached to the tool via a pivot coupling.
Clause 15: A method of assembling a steering head of a rotary steerable tool for steering a drill string, wherein the steering head includes a steering pad and a piston formed as a pad pusher having first and second motion restrictors, and a housing having first and second motion restrictors, the method comprising: positioning the pad pusher with respect to the housing to align each of the first and second motion restrictors of the pad pusher with the respective first and second motion restrictors of the housing; engaging (1) the first motion restrictor of the pad pusher with the first motion restrictor of the housing, and (2) the second motion restrictor of the pad pusher with the second motion restrictor of the housing to restrict a rotational motion the steering pad relative to the housing; and pivotally coupling the pad pusher to the housing about a pivot axis of the steering pad, wherein the pad pusher is rotatable about the pivot axis between retracted and extended positions.
Clause 16: The method of Clause 15, further comprising coupling the pad pusher to a collar of the tool via the housing.
Clause 17: The method of Clause 16, wherein the pad pusher motion restrictor comprises a first motion restrictor at an uphole side thereof, and a second motion restrictor at a downhole side thereof, and the housing motion restrictor comprises a first motion restrictor at an uphole side thereof, and a second motion restrictor at a downhole side thereof, the method further comprising: restricting the motion of the steering pad relative to the housing by engaging (1) the first motion restrictor of the pad pusher with the first motion restrictor of the housing, and (2) the second motion restrictor of the pad pusher with the second motion restrictor of the housing.
Clause 18: The method of Clause 17, wherein: the first motion restrictor of the pad pusher comprises one of a first motion-limiting protrusion or a first retaining recess, and the first motion restrictor of the housing comprises a remaining one of the first motion-limiting protrusion or the first retaining recess; and the second motion restrictor of the pad pusher comprises one of a second motion-limiting protrusion or a second retaining recess, and the second motion restrictor of the housing comprises a remaining one of the second motion-limiting protrusion or the second retaining recess;
The steering head of Clause 18, wherein: the first and second motion restrictors of the pad pusher comprise first and second motion-limiting protrusions extending laterally from the respective uphole and downhole sides; and the first and second motion restrictors of the housing comprise first and second retaining recesses respectively, configured to receive the respective first and second motion-limiting protrusions therein.
Clause 19: The method of Clause 18, wherein a cross-section of each of the first and second motion-limiting protrusions tapers in size in a direction from the downhole side to the uphole side of the steering pad.
Clause 20: The method of Clause 19, wherein the size comprises a height of the cross-section of each of the first and second motion-limiting protrusions.
Clause 21: The method of Clause 18, wherein each of the first and second motion-limiting protrusions each comprise a first edge, a second edge parallel to and disposed below the first edge, and a third edge angularly positioned with respect to the first and second edges.
Clause 22: The method of Clause 21, wherein in a fully retracted position of the pad pusher, the third edge is positioned parallel to a bottom edge of the respective first and second retaining recesses.
Clause 23: The method of Clause 21, wherein in a fully extended position of the pad pusher, the first edge abuts a top edge of the respective first and second retaining recesses to restrict further rotation of the pad pusher about the pivot axis in a first direction.
Clause 24: The method of Clause 23, wherein in the fully extended position of the pad pusher, the first edge extends parallel to the top edge of the respective first and second retaining recesses to restrict further rotation of the pad pusher about the pivot axis in a first direction.
Filing Document | Filing Date | Country | Kind |
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PCT/US2018/020783 | 3/2/2018 | WO | 00 |
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WO2019/133034 | 7/4/2019 | WO | A |
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