Not applicable.
It has become increasingly common in the oil and gas industry to use “directional drilling” techniques to drill horizontal and other non-vertical wellbores, to facilitate more efficient access to and production from larger regions of subsurface hydrocarbon-bearing formations than would be possible using only vertical wellbores. In directional drilling, specialized drill string components and “bottomhole assemblies” (BHAs) are used to induce, monitor, and control deviations in the path of the drill bit, so as to produce a wellbore of desired non-vertical configuration.
Directional drilling is typically carried out using a “downhole motor” (alternatively referred to as a “mud motor”) incorporated into the drill string immediately above the drill bit. A typical mud motor generally includes a top sub adapted to facilitate connection to the lower end of a drill string, a power section comprising a positive displacement motor of well-known type with a helically-vaned rotor eccentrically rotatable within a stator section, a drive shaft enclosed within a drive shaft housing, with the upper end of the drive shaft being operably connected to the rotor of the power section, and a bearing section comprising a cylindrical mandrel coaxially and rotatably disposed within a cylindrical housing, with an upper end coupled to the lower end of the drive shaft, and a lower end adapted for connection to a drill bit. The mandrel is rotated by the drive shaft, which rotates in response to the flow of drilling fluid under pressure through the power section, while the mandrel rotates relative to the cylindrical housing, which is connected to the drill string. Directional drilling allows the well to be drilled out at an angle. A bent housing motor is used to form a curved well path. The bent housing is often located above the bearing section and below the power section.
The wellbore of at least some drilling systems includes a vertical section extending from the surface, a curved section extending from a lower end of the vertical section, and a lateral section extending from the curved section. A trip to the surface of the wellbore for the downhole motor may be required to change a bend setting on the downhole motor as the drill bit and downhole motor of the drilling system enters a new section of the wellbore. For instance, in at least some applications the vertical section of the wellbore may be drilled with the downhole motor disposed at approximately a 0.5-1 degree bend to allow small corrections when needed to maintain verticality (e.g., inclination below 5 degrees), but still give an operator of the drilling system the ability to rotary drill spinning the downhole motor at relatively higher rotational speeds (e.g., 30-100 revolutions per minute (RPM)) to allow faster rates of penetration (ROPs) without damaging the downhole motor. Bend settings of the downhole motor greater than 1 degree and rotary RPM over 50 RPM may lead to premature failure of a bearing assembly and/or a bend housing of the downhole motor or motor adjustable housing in at least some applications.
In some applications, the curved section of the wellbore may demand a bend setting of the downhole motor of approximately 1-3 degrees or greater to achieve an inclination or curve of approximately 3-16 degrees/100 feet. Bend settings of the downhole motor 1-3 degrees or greater generally do not allow for the rotational speeds above approximately 50 RPM. Because of this limitation another trip to the surface of the wellbore may be required to reduce the bend setting of the downhole motor once the operator reaches the lateral section of the wellbore. The high bend setting required by the curved section is typically not needed in the lateral section of the wellbore, and thus, a downhole motor having a bend setting of approximately 0.5-1.5 degrees may be utilized to drill the lateral section of the wellbore and thereby maintain the desired inclination while drilling at high ROPs.
During a directional drilling operation, sensors associated with the downhole motor (measurement while drilling (MWD) sensors, etc.) can fail, and/or the wellbore can have severe stick slip causing tool damage and eventual failure. Typically, when the drilling system does not include a rotary steerable system (RSS) positioned below the downhole motor the total RPM of the drill bit and other critical data cannot be collected. Generally, conventional downhole motor technology utilizes fixed bent housings or externally adjustable housings that allow a range of bend settings of the downhole motor to be chosen and locked in place at the surface of the wellbore, not allowing the operator of the drilling system to change the bend setting of the mud motor downhole. RSS tools generally allow the operator to effectively change the amount of steering the RSS tool offers via downlinks or some sort of communication from the surface of the wellbore, but RSS tools may be relatively expensive and complex to operate compared to conventional downhole motors. RSS tools also do not generally have the reliability of a downhole motor and typically have a Lost in Hole (LIH) cost approximately 3-10 times that of a conventional bent motor.
RSS tools also allow the use of electronics to collect data on inclination, vibration, and stick slip during downhole operation. This data may be valuable to operators when tuning parameters to extend drilling intervals downhole and limit damage to tools. Conventional downhole motors typically do not collect data on total bit RPM, torque, stick slip, vibration, and inclination. Further, logging tools are typically not short enough to be housed below the downhole motor without being a detriment to the downhole motor's build rate. Conventional commercial logging tools may be either collar based and run above the downhole motor or collar based and run in a short sub below the downhole motor near the drill bit. Generally, running tools positioned below the downhole motor may increase the bit to bend distance of the downhole motor and thus decrease the build rate of the downhole motor.
An embodiment of a downhole motor for directional drilling comprises a driveshaft assembly including a driveshaft housing and a driveshaft rotatably disposed within the driveshaft housing, a bearing assembly including a bearing housing and a bearing mandrel rotatably disposed within the bearing housing, wherein the bearing mandrel is configured to couple with a drill bit, a bend adjustment assembly including a first position that provides a first deflection angle between a longitudinal axis of the driveshaft housing and a longitudinal axis of the bearing mandrel, and a second position that provides a second deflection angle between the longitudinal axis of the driveshaft housing and the longitudinal axis of the bearing mandrel that is different from the first deflection angle, and one or more hydraulic pumps configured to actuate the bend adjustment assembly between the first position and the second position. In some embodiments, the downhole motor comprises a lock piston comprising an unlocked position, and a locked position configured to lock the bend adjustment assembly into one of the first position and the second position. In some embodiments, at least one of the one or more hydraulic pumps is configured to actuate the lock piston between the unlocked position and the locked position. In certain embodiments, the downhole motor comprises an electronics package configured to indicate whether the lock piston in the unlocked position or the locked position. In certain embodiments, the downhole motor comprises an actuator piston configured to, in response to actuating the actuator piston from a deactivated position to an activated position, actuate the bend adjustment assembly between the first position and the second position. In some embodiments, at least one of the one or more hydraulic pumps is configured to actuate the actuator piston between the deactivated position and the activated position. In some embodiments, the downhole motor comprises an electronics package configured to indicate whether the actuator piston in the deactivated position or the activated position. In some embodiments, the downhole motor comprises an electronics package configured to indicate the whether the bend adjustment assembly is in the first position or the second position. In certain embodiments, the downhole motor comprises an electronics package comprising an electromagnetic communication link for controlling the operation of the one or more hydraulic pumps from the surface. In certain embodiments, the downhole motor comprises an electronics package configured to control the actuation of the one or more hydraulic pumps.
An embodiment of a downhole motor for directional drilling comprises a driveshaft assembly including a driveshaft housing and a driveshaft rotatably disposed within the driveshaft housing, a bearing assembly including a bearing housing and a bearing mandrel rotatably disposed within the bearing housing, wherein the bearing mandrel is configured to couple with a drill bit, a bend adjustment assembly configured to adjust a bend setting of the downhole motor, and an electronics package configured to indicate the bend setting of the bend adjustment assembly. In some embodiments, the downhole motor comprises a lock piston comprising an unlocked position, and a locked position configured to lock the bend setting of the bend adjustment assembly. In some embodiments, the electronics package is configured to indicate whether lock piston is in the locked position or the unlocked position. In certain embodiments, the downhole motor comprises a hydraulic pump configured to actuate the lock piston into the unlocked position to unlock the bend adjustment assembly. In certain embodiments, the downhole motor comprises a solenoid valve configured to lock the lock piston into at least one of the locked and unlocked positions in response to receiving a locking signal. In some embodiments, the bend adjustment assembly comprises an actuator piston configured to, in response to actuating the actuator piston from a deactivated position to an activated position, actuate the bend adjustment assembly between a first position that provides a first deflection angle between a longitudinal axis of the driveshaft housing and a longitudinal axis of the bearing mandrel, and a second position that provides a second deflection angle between the longitudinal axis of the driveshaft housing and the longitudinal axis of the bearing mandrel that is different from the first deflection angle. In some embodiments, the electronics package is configured to indicate whether the actuator piston is in the deactivated position or the activated position. In some embodiments, the electronics package comprises an electromagnetic short hop transmitter configured to communicate with an electromagnetic short hop receiver disposed in a measurement-while-drilling (MWD) tool coupled to the downhole motor. In certain embodiments, the electronics package comprises an electromagnetic communication link. In certain embodiments, the downhole motor comprises one or more hydraulic pumps configured to actuate the bend adjustment assembly includes a first position that provides a first deflection angle between a longitudinal axis of the driveshaft housing and a longitudinal axis of the bearing mandrel, and a second position that provides a second deflection angle between the longitudinal axis of the driveshaft housing and the longitudinal axis of the bearing mandrel that is different from the first deflection angle.
For a detailed description of exemplary embodiments of the disclosure, reference will now be made to the accompanying drawings in which:
The following discussion is directed to various exemplary embodiments. However, one skilled in the art will understand that the examples disclosed herein have broad application, and that the discussion of any embodiment is meant only to be exemplary of that embodiment, and not intended to suggest that the scope of the disclosure, including the claims, is limited to that embodiment. Certain terms are used throughout the following description and claims to refer to particular features or components. As one skilled in the art will appreciate, different persons may refer to the same feature or component by different names. This document does not intend to distinguish between components or features that differ in name but not function. The drawing figures are not necessarily to scale. Certain features and components herein may be shown exaggerated in scale or in somewhat schematic form and some details of conventional elements may not be shown in interest of clarity and conciseness.
In the following discussion and in the claims, the terms “including” and “comprising” are used in an open-ended fashion, and thus should be interpreted to mean “including, but not limited to . . . .” Also, the term “couple” or “couples” is intended to mean either an indirect or direct connection. Thus, if a first device couples to a second device, that connection may be through a direct connection, or through an indirect connection via other devices, components, and connections. In addition, as used herein, the terms “axial” and “axially” generally mean along or parallel to a central axis (e.g., central axis of a body or a port), while the terms “radial” and “radially” generally mean perpendicular to the central axis. For instance, an axial distance refers to a distance measured along or parallel to the central axis, and a radial distance means a distance measured perpendicular to the central axis. Any reference to up or down in the description and the claims is made for purposes of clarity, with “up”, “upper”, “upwardly”, “uphole”, or “upstream” meaning toward the surface of the borehole and with “down”, “lower”, “downwardly”, “downhole”, or “downstream” meaning toward the terminal end of the borehole, regardless of the borehole orientation. Further, the term “fluid,” as used herein, is intended to encompass both fluids and gasses.
Referring to
Power section 40 of BHA 30 converts the fluid pressure of the drilling fluid pumped downward through drillstring 21 into rotational torque for driving the rotation of drill bit 90. Driveshaft assembly 102 and bearing assembly 200 of mud motor 35 transfer the torque generated in power section 40 to bit 90. With force or weight applied to the drill bit 90, also referred to as weight-on-bit (“WOB”), the rotating drill bit 90 engages the earthen formation and proceeds to form borehole 16 along a predetermined path toward a target zone. The drilling fluid or mud pumped down the drillstring 21 and through BHA 30 passes out of the face of drill bit 90 and back up the annulus 18 formed between drillstring 21 and the sidewall 19 of borehole 16. The drilling fluid cools the bit 90, and flushes the cuttings away from the face of bit 90 and carries the cuttings to the surface.
Referring to
During operation of the hydraulic drive section 40, fluid is pumped under pressure into one end of the hydraulic drive section 40 where it fills a first set of open cavities 70. A pressure differential across the adjacent cavities 70 forces the rotor 50 to rotate relative to the stator 60. As the rotor 50 rotates inside the stator 60, adjacent cavities 70 are opened and filled with fluid. As this rotation and filling process repeats in a continuous manner, the fluid flows progressively down the length of hydraulic drive section 40 and continues to drive the rotation of the rotor 50. Driveshaft assembly 102 shown in
In the embodiment of
In general, driveshaft assembly 102 functions to transfer torque from the eccentrically-rotating rotor 50 of power section 40 to a concentrically-rotating bearing mandrel 202 of bearing assembly 200 and drill bit 90. In this embodiment, bearing mandrel 202 includes a central bore or passage 203 that receives a flow of drilling fluid supplied to mud motor 35. Additionally, bearing assembly 200 includes a bearing housing 210 in which bearing mandrel 202 is rotatably disposed, and a sealed oil chamber 213 positioned radially between bearing housing 210 and bearing mandrel 202 and is sealed from central passage 203 of bearing mandrel 202. Additionally, bearing assembly 200 includes a rotary bearing (e.g., a thrust bearing, etc.) positioned in sealed oil chamber 213 for supporting relative rotation between bearing housing 210 and bearing mandrel 202.
As best shown in
Referring to
A first or upper end 106A of driveshaft 106 is pivotally coupled to the lower end of rotor 50 (not shown in
In some embodiments, the driveshaft adapter 120 of mud motor 35 may include other electronics and sensor packages. For instance, referring briefly to
In some embodiments, instead of including a short hop transmitter, electronics package 138 includes a data port positionable in the upper end of rotor 50 of mud motor 130 for field data downloads. In some embodiments, drillstring 21, from which mud motor 130 is suspended, comprises a plurality of wired drill pipe joints (WDP joints) where the short hop transmitter of electronics package 138 permits communication between electronics of mud motor 130 and electronics positioned downhole from mud motor 130 with a MWD tool disposed uphole from mud motor 130 that is connected with the WDP joints of drillstring 21.
Referring to
As will be discussed further herein, bend adjustment assembly 300 of mud motor 250 is configured to actuate between a first or unbent position 303 (shown in
Bend adjustment assembly 300 couples driveshaft housing 104″ to bearing housing 210, and selectably introduces deflection angle θ (shown in
In this embodiment, bend adjustment assembly 300 generally includes a first or upper housing 302, an upper housing extension 310 (shown in
As shown particularly in
As shown particularly in
Additionally, lower offset housing 320 includes a central bore or passage 329 extending between lower end 320B and internal shoulder 327S, where central passage 329 has a central axis disposed at an angle relative to a central axis of offset bore 327. In other words, offset engagement surface 323 has a central or longitudinal axis that is offset or disposed at an angle relative to a central or longitudinal axis of lower offset housing 320. Thus, in this embodiment, the offset or angle formed between central bore 329 and offset bore 327 of lower offset housing 320 facilitates the formation of bend 101 described above. In this embodiment, the inner surface 322 of lower offset housing 320 additionally includes an internal lower annular shoulder 325 (shown in
In this embodiment, lower offset housing 320 of bend adjustment assembly 300 includes an arcuate, axially extending locking member or shoulder 328 at upper end 320A. Particularly, locking shoulder 328 extends arcuately between a pair of axially extending shoulders 328S. In this embodiment, locking shoulder 328 extends less than 180° about the central axis of lower offset housing 320; however, in other embodiments, the arcuate length or extension of locking shoulder 328 may vary. Additionally, lower offset housing 320 includes a plurality of circumferentially spaced and axially extending ports 330. Particularly, ports 330 extend axially between internal shoulders 325, 326 of lower offset housing 320. As will be discussed further herein, ports 330 of lower offset housing 320 provide fluid communication through a generally annular compensation or locking chamber 395 (shown in
As shown particularly in
In this embodiment, the inner surface 342 of actuator housing 340 includes a threaded connector at lower end 340B, an annular shoulder 346, and a port 347 that extends radially between inner surface 342 and the outer surface of actuator housing 340. A threaded connector positioned on the inner surface 342 of actuator housing 340 couples with a corresponding threaded connector disposed on an outer surface of bearing housing 210 at an upper end thereof to thereby couple bend adjustment assembly 300 with bearing assembly 200. In this embodiment, the inner surface 342 of actuator housing 340 additionally includes an annular seal 348 located proximal shoulder 346 and a plurality of circumferentially spaced and axially extending slots or grooves 349. As will be discussed further herein, seal 348 and slots 349 are configured to interface with components of locker assembly 400.
As shown particularly in
Also as shown particularly in
In this embodiment, upper adjustment mandrel 360 includes a generally cylindrical outer surface comprising a first or upper threaded connector, and an offset engagement surface 365. The upper threaded connector extends from upper end 360A and couples to a threaded connector disposed on the inner surface of driveshaft housing 104″ at a lower end thereof. Offset engagement surface 365 has a central or longitudinal axis that is offset from or disposed at an angle relative to a central or longitudinal axis of upper adjustment mandrel 360. Offset engagement surface 365 matingly engages the engagement surface 316 of housing extension 310. In this embodiment, relative rotation is permitted between upper housing 302 and upper adjustment mandrel 360 while relative axial movement is restricted between housing 302 and mandrel 360.
As shown particularly in
In this embodiment, an annular seal 373 is disposed in the outer surface of lower adjustment mandrel 370 to sealingly engage the inner surface of lower housing 320. In this embodiment, relative rotation is permitted between lower housing 320 and lower adjustment mandrel 370. Arcuate recess 374 is defined by an inner terminal end 374E and a pair of circumferentially spaced shoulders 375. In this embodiment, lower adjustment mandrel 370 further includes a pair of circumferentially spaced first or short slots 376 and a pair of circumferentially spaced second or long slots 378, where both short slots 376 and long slots 378 extend axially into lower adjustment mandrel 370 from lower end 370B. In this embodiment, each short slot 376 is circumferentially spaced approximately 180° apart. Similarly, in this embodiment, each long slot 378 is circumferentially spaced approximately 180° apart.
As shown particularly in
In this embodiment, the combination of sealing engagement between seals 382A, 382B of locking piston 380 and the inner surface 322 of lower housing 320, defines a lower axial end of locking chamber 395. Locking chamber 395 extends longitudinally from the lower axial end thereof to an upper axial end defined by the combination of sealing engagement between the outer seal 358A of compensating piston 356 and the inner seal 358B of piston 356. Particularly, lower adjustment mandrel 370 and upper adjustment mandrel 360 each include axially extending ports, including ports 368 formed in upper adjustment mandrel 360, similar in configuration to the ports 330 of lower housing 320 such that fluid communication is provided between the annular space directly adjacent shoulder 386 of locking piston 380 and the annular space directly adjacent a lower end of compensating piston 356. Locking chamber 395 is sealed such that drilling fluid flowing through mud motor 250 to drill bit 90 is not permitted to communicate with fluid disposed in locking chamber 395, where locking chamber 395 is filled with lubricant (e.g., an oil-based lubricant).
As shown particularly in
In this embodiment, seal 406 of actuator piston 402 sealingly engages the inner surface 342 of actuator housing 340 and an annular seal positioned on an inner surface of teeth ring 420 sealingly engages the outer surface of bearing mandrel 202. Additionally, the seal 348 of actuator housing 340 sealingly engages the outer surface of actuator piston 402 to form an annular, sealed compensating chamber 412 extending therebetween. Fluid pressure within compensating chamber 410 is compensated or equalized with the surrounding environment (e.g., borehole 16) via port 347 of actuator housing 340. Additionally, an annular biasing member 412 is disposed within compensating chamber 410 and applies a biasing force against shoulder 404 of actuator piston 402 in the axial direction of teeth ring 420. Teeth ring 420 of locker assembly 400 is generally tubular and comprises a first or upper end 420A, a second or lower end 420B, and a central bore or passage extending between ends 420A and 420B. Teeth ring 420 is coupled to bearing mandrel 202 via a plurality of circumferentially spaced splines or pins disposed radially therebetween. In this arrangement, relative axial and rotational movement between bearing mandrel 202 and teeth ring 420 is restricted. Additionally, in this embodiment, teeth ring 420 comprises a plurality of circumferentially spaced teeth 424 extending from upper end 420A. Teeth 424 of teeth ring 420 are configured to matingly engage or mesh with the teeth 410 of actuator piston 402 when biasing member 412 biases actuator piston 402 into contact with teeth ring 420, as will be discussed further herein.
As shown particularly in
In some embodiments, locker assembly 400 permits rotation in mud motor 250 to rotate rotor 50 and bearing mandrel 202 until bend adjustment assembly 300 has fully actuated, and then, subsequently, ratchet or slip while transferring relatively large amounts of torque to bearing housing 210. This reaction torque may be adjusted by increasing the hydraulic force or hydraulic pressure acting on actuator piston 402, which may be accomplished by increasing flowrate through mud motor 250. When additional torque is needed a lower flowrate or fluid pressure can be applied to locker assembly 400 to modulate the torque and thereby rotate bend adjustment assembly 300. The fluid pressure is transferred to actuator piston 402 by compensating piston 226. In some embodiments, the pressure drop across drill bit 90 may be used to increase the pressure acting on actuator piston 402 as flowrate through mud motor 250 is increased. Additionally, ratcheting of locker assembly 400 once bend adjustment assembly 300 reaches a fully bent position may provide a relatively high torque when teeth 424 are engaged and riding up the ramp and a very low torque when locker assembly 400 ratchets to the next tooth when the slipping torque value has been reached (locker assembly 400 catching again after it slips one tooth of teeth 424). This behavior of locker assembly 400 may provide a relatively good pressure signal indicator that bend adjustment assembly 300 has fully actuated and is ready to be locked.
As described above, bend adjustment assembly 300 includes unbent position 303 and a bent position providing deflection angle θ. In this embodiment, central axis 105 of driveshaft housing 104″ is parallel with, but laterally offset from central axis 215 of bearing mandrel 202 when bend adjustment assembly 300 is in unbent position 303; however, in other embodiments, driveshaft housing 104″ may comprise a fixed bent housing providing an angle between axes 115 and 215 when bend adjustment assembly 300 is in unbent position 303. Locker assembly 400 is configured to control or facilitate the downhole or in-situ actuation or movement of bend adjustment assembly between unbent position 303 and the bent position. As will be described further herein, in this embodiment, bend adjustment assembly 300 is configured to shift from unbent position 303 to the bent position in response to rotation of lower housing 320 in a first direction relative to lower adjustment mandrel 370, and shift from the bent position to the unbent position 303 in response to rotation of lower housing 320 in a second direction relative to lower adjustment mandrel 370 that is opposite the first direction.
Still referring to
As described above, offset bore 327 and offset engagement surface 323 of lower housing 320 are offset from central bore 329 and the central axis of housing 320 to form a lower offset angle, and offset engagement surface 365 of upper adjustment mandrel 360 is offset from the central axis of mandrel 360 to form an upper offset angle. Additionally, offset engagement surface 323 of lower housing 320 matingly engages the engagement surface 372 of lower adjustment mandrel 370 while the engagement surface 314 of housing extension 310 matingly engages the offset engagement surface 365 of upper adjustment mandrel 360. In this arrangement, the relative angular position between lower housing 320 and lower adjustment mandrel 370 determines the total offset angle (ranging from 0° to a maximum angle greater than 0°) between the central axes of lower housing 320 and driveshaft housing 104″.
The minimum angle (0° in this embodiment) occurs when the upper and lower offsets are in-plane and cancel out, while the maximum angle occurs when the upper and lower offsets are in-plane and additive. Therefore, by adjusting the relative angular positions between offset housings 310, 320, and adjustment mandrels 360, 370, the deflection angle θ and bend 101 of bend adjustment assembly 300 may be adjusted or manipulated in-turn. The magnitude of bend 101 is controlled by the relative positioning of shoulders 328S and shoulders 375, which establish the extents of angular rotation in each direction. In this embodiment, lower housing 320 is provided with a fixed amount of spacing between shoulders 328S, while adjustment mandrel 370 can be configured with an optional amount of spacing between shoulders 375, allowing the motor to be set up with the desired bend setting options as dictated by a particular job simply by providing the appropriate configuration of lower adjustment mandrel 370.
Also as described above, locker assembly 400 is configured to control the actuation of bend adjustment assembly 300, and thereby, control the degree of bend 101. In this embodiment, locker assembly 400 is configured to selectively or controllably transfer torque from bearing mandrel 202 (supplied by rotor 50) to actuator housing 340 in response to changes in the flowrate of drilling fluid supplied to power section 40. Particularly, in this embodiment, to actuate bend adjustment assembly 300 from unbent position 303 to the bent position, the pumping of drilling mud from surface pump 23 and the rotation of drillstring 21 by rotary system 24 is ceased. Particularly, the pumping of drilling mud from surface pump 23 is ceased for a predetermined first time period. In some embodiments, the first time period over which pumping is ceased from surface pump 23 comprises approximately 15-120 seconds; however, in other embodiments, the first time period may vary. With the flow of drilling fluid to power section 40 ceased during the first time period, fluid pressure applied to the lower end 380B of locking piston 380 (from drilling fluid in annulus 116) is reduced, while fluid pressure applied to the upper end 380A of piston 380 is maintained, where the fluid pressure applied to upper end 380A is from lubricant disposed in locking chamber 395 that is equalized with the fluid pressure in borehole 16 via ports 114 and locking piston 356. With the fluid pressure acting against lower end 380B of locking piston 380 reduced, the biasing force applied to the upper end 380A of piston 380 via biasing member 354 (the force being transmitted to upper end 380A via the fluid disposed in locking chamber 395) is sufficient to displace or actuate locking piston 380 from the locked position with keys 384 received in long slots 378 of lower adjustment mandrel 370, to the unlocked position with keys 384 free from long slots 378, thereby unlocking offset housings 310, 320, from adjustment mandrels 360, 370. In this manner, locking piston 380 comprises a first locked position with keys 384 receives in short slots 376 of lower adjustment mandrel 370 and a second locked position, which is axially spaced from the first locked position, with keys 384 receives in long slots 378 of lower adjustment mandrel 370.
In this embodiment, directly following the first time period, surface pump 23 resumes pumping drilling mud into drillstring 21 at a first flowrate that is reduced by a predetermined percentage from a maximum mud flowrate of well system 10, where the maximum mud flowrate of well system 10 is dependent on the application, including the size of drillstring 21 and BHA 30. For instance, the maximum mud flowrate of well system 10 may comprise the maximum mud flowrate that may be pumped through drillstring 21 and BHA 30 before components of drillstring 21 and/or BHA 30 are eroded or otherwise damaged by the mud flowing therethrough. In some embodiments, the first flowrate of drilling mud from surface pump 23 comprises approximately 1%-30% of the maximum mud flowrate of well system 10; however, in other embodiments, the first flowrate may vary. For instance, in some embodiments, the first flowrate may comprise zero or substantially zero fluid flow. In this embodiment, surface pump 23 continues to pump drilling mud into drillstring 21 at the first flowrate for a predetermined second time period while rotary system 24 remains inactive. In some embodiments, the second time period comprises approximately 15-120 seconds; however, in other embodiments, the second time period may vary.
During the second time period with drilling mud flowing through BHA 30 from drillstring 21 at the first flowrate, rotational torque is transmitted to bearing mandrel 202 via rotor 50 of power section 40 and driveshaft 106. Additionally, biasing member 412 applies a biasing force against shoulder 404 of actuator piston 402 to urge actuator piston 402 into contact with teeth ring 420, with teeth 410 of piston 402 in meshing engagement with the teeth 424 of teeth ring 420. In this arrangement, torque applied to bearing mandrel 202 is transmitted to actuator housing 340 via the meshing engagement between teeth 424 of teeth ring 420 (rotationally fixed to bearing mandrel 202) and teeth 410 of actuator piston 402 (rotationally fixed to actuator housing 340). Rotational torque applied to actuator housing 340 via locker assembly 400 is transmitted to offset housings 310, 320, which rotate (along with bearing housing 210) in a first rotational direction relative adjustment mandrels 360, 370. Particularly, extension 328 of lower housing 320 rotates through arcuate recess 374 of lower adjustment mandrel 370 until a shoulder 328S engages a corresponding shoulder 375 of recess 374, restricting further relative rotation between offset housings 310, 320, and adjustment mandrels 360, 370. Following the rotation of lower housing 320, bend adjustment assembly 300 is disposed in the bent position providing bend 101. Additionally, although during the actuation of bend adjustment assembly 300 drilling fluid flows through mud motor 250 at the first flowrate, the first flowrate is not sufficient to overcome the biasing force provided by biasing member 354 against locking piston 380 to thereby actuate locking piston 380 back into the locked position.
In this embodiment, directly following the second time period, with bend adjustment assembly 300 disposed in the bent position, the flowrate of drilling mud from surface pump 23 is increased from the first flowrate to a second flowrate that is greater than the first flowrate. In some embodiments, the second flowrate of drilling mud from surface pump 23 comprises approximately 50%-100% of the maximum mud flowrate of well system 10; however, in other embodiments, the second flowrate may vary. Following the second time period with drilling mud flowing through BHA 30 from drillstring 21 at the second flowrate, the fluid pressure applied to the lower end 380B of locking piston 380 is sufficiently increased to overcome the biasing force applied against the upper end 380A of piston 380 via biasing member 354, actuating or displacing locking piston 380 from the unlocked position to the locked position with keys 384 received in short slots 376, thereby rotationally locking offset housings 310, 320, with adjustment mandrels 360, and 370.
Additionally, with drilling mud flowing through BHA 30 from drillstring 21 at the second flowrate, fluid pressure applied against the lower end 402B of actuator piston 402 from the drilling fluid (such as through leakage of the drilling fluid in the space disposed radially between the inner surface of actuator piston 402 and the outer surface of bearing mandrel 202) is increased, overcoming the biasing force applied against shoulder 404 by biasing member 412 and thereby disengaging actuator piston 402 from teeth ring 420. With actuator piston 402 disengaged from teeth ring 420, torque is no longer transmitted from bearing mandrel 202 to actuator housing 340. In some embodiments, as borehole 16 is drilled with bend adjustment assembly 300 in the bent position, additional pipe joints may need to be coupled to the upper end of drillstring 21, necessitating the stoppage of the pumping of drilling fluid to power section 40 from surface pump 23. In some embodiments, following such a stoppage, the steps described above for actuating bend adjustment assembly 300 into the bent position may be repeated to ensure that assembly 300 remains in the bent position.
On occasion, it may be desirable to actuate bend adjustment assembly 300 from the bent position to the unbent position 303. In this embodiment, bend adjustment assembly 300 is actuated from the bent position to the unbent position 303 by ceasing the pumping of drilling fluid from surface pump 23 for a predetermined third period of time. Either concurrent with the third time period or following the start of the third time period, rotary system 24 is activated to rotate drillstring 21 at a first or actuation rotational speed for a predetermined fourth period of time. In some embodiments, both the third time period and the fourth time period each comprise approximately 15-120 seconds; however, in other embodiments, the third time period and the fourth time period may vary. Additionally, in some embodiments, the rotational speed comprises approximately 1-30 revolutions per minute (RPM) of drillstring 21; however, in other embodiments, the actuation rotational speed may vary. During the fourth time period, with drillstring 21 rotating at the actuation rotational speed, reactive torque is applied to bearing housing 210 via physical engagement between an outer surface of bearing housing 210 and the sidewall 19 of borehole 16, thereby rotating bearing housing 210 and offset housings 310, 320, relative to adjustment mandrels 360, 370 in a second rotational direction opposite the first rotational direction described above. Rotation of lower housing 320 causes shoulder 328 to rotate through recess 374 of lower adjustment mandrel 370 until a shoulder 328S physically engages a corresponding shoulder 375 of recess 374, restricting further rotation of lower housing 320 in the second rotational direction.
In this embodiment, following the third and fourth time periods (the fourth time period ending either at the same time as the third time period or after the third time period has ended), with bend adjustment assembly 300 disposed in the unbent position 303, drilling mud is pumped through drillstring 21 from surface pump 23 at a third flowrate for a predetermined fifth period of time while drillstring 21 is rotated by rotary system 24 at the actuation rotational speed. In some embodiments, the fifth period of time comprises approximately 15-120 second and the third flowrate of drilling mud from surface pump 23 comprises approximately 30%-80% of the maximum mud flowrate of well system 10; however, in other embodiments, the firth period of time and the third flowrate may vary.
Following the fifth period of time, the flowrate of drilling mud from surface pump 23 is increased from the third flowrate to a flowrate near or at the maximum mud flowrate of well system 10 to thereby disengage locker assembly 400 and dispose locking piston 380 in the locked position. Once surface pump 23 is pumping drilling mud at the drilling or maximum mud flowrate of well system 10, rotation of drillstring 21 via rotary system 24 may be ceased or continued at the actuation rotational speed. With drilling mud being pumped into drillstring 21 at the third flowrate and the drillstring 21 being rotated at the actuation rotational speed, locker assembly 400 is disengaged and locking piston 380 is disposed in the locked position with keys 384 received in long slots 378 of lower adjustment mandrel 370.
With locker assembly 300 disengaged and locking piston 380 disposed in the locked position drilling of borehole 16 via BHA 30 may be continued with surface pump 23 pumping drilling mud into drillstring 21 at or near the maximum mud flowrate of well system 10. In other embodiments, instead of surface pump 23 at the third flowrate for a period of time following the third and fourth time periods, surface pump 23 may be operated immediately at 100% of the maximum mud flowrate of well system 10 to disengage locker assembly 400 and dispose locking piston 380 in the locked position. Once surface pump 23 is pumping drilling mud at the drilling or maximum mud flowrate of well system 10, rotation of drillstring 21 via rotary system 24 may be ceased or continued at the actuation rotational speed.
In certain embodiments, electronics package 125 of mud motor 250 provides for the ability to confirm the position of and/or actuate the bend adjustment assembly 300 of mud motor 250 between unbent position 303 and the bent positions electronically with wired connections that can pass power to downhole electric hydraulic pumps and solenoids positioned in mud motor 250. In some embodiments, bend adjustment assembly 300 is actuated from the surface via electronics package 125 using a downlinking method, such as the downlinking method described in U.S. Pat. No. 9,488,045, which is incorporated herein by reference for all of its teachings. In some embodiments, electronics package 125 can be replaced with electronics package 138 to provide added functionality as described above. This added functionality could be real-time measurements of the adjustable sensors to be passed to a MWD tools above mud motor 250. In certain embodiments, electronics package 125 of mud motor 250 comprises a puck with a recess or a spacer ring placed on top of the puck to allow a thrust piece of driveshaft 106 to be placed properly. In some embodiments, electronics package 125 comprises a BlackBoxHD, BlackBox Eclipse and Blackbox EMS provided by National Oilwell Varco located at 7909 Parkwood Circle Drive, Houston, Tex. 77036. In some embodiments, electronics package 125 includes features in common with the electronics packages and sensor assemblies described in U.S. Pat. No. 8,487,626, which is incorporated herein by reference for all of its teachings.
In some embodiments, electronics package 125 comprises a pressure data logger electronics board with one or two pressure sensors coupled to driveshaft adapter 120 to allow seal boot pressure, downhole pressure and bit drop pressures to all be monitored. By extending a passage to a bore of rotor 50 of mud motor 250 and passing wires to an additional pressure sensor mounted on the upper end 120A of the driveshaft adapter 120, internal differential pressure across mud motor 250 may be obtained. This is accomplished as the inner diameter of the rotors pressure would give the pressure at the top of rotor 50. Additionally, if the second pressure sensor takes a pressure reading of the seal boot pressure then a differential pressure across the rotor 50 of mud motor 250 may be obtained. By knowing the differential pressure across the rotor 50, a relatively accurate estimate of the torque output of the power section 40 of mud motor 250 may be determined. Particularly, each power section of a mud motor (e.g., power section 40 of mud motor 250) has a performance chart where a specific pressure across the rotor equals a specific torque output. Alternately, in some embodiments, the center of the rotor 50 of mud motor 250 could be used to house batteries when a ported rotor is not needed and the wires leading up to the upper end of driveshaft adapter 120 could use a connector that would allow the batteries to be slid into the bore of the rotor 50 from the up hole side and then capped off with a sealing cap to house more power consuming electronics for formation logging or surveying as described in
Alternately, the lengthened driveshaft adapter 132 shown in
The addition of electronic sensors in universal joint 110A and/or in the driveshaft adapter (e.g., driveshaft adapters 120, 132) followed by a wire exiting the top of the driveshaft adapter could allow placement of a short hop transmitter (e.g., as part of electronics package 138) positioned near bit (e.g., within 10 feet of drill bit 90 in some applications). The batteries used to power the short hop transmitter could be housed inside the rotor of mud motor 250 and connected to the wire exiting the top of the driveshaft adapter 132. Additionally, an antennae or transmitter could be stacked above the rotor 50 of mud motor 250 in a modified rotor catch with antennae inside in order to decrease the overall length of the short hop transmitter's unconnected jump distance to the MWD tool disposed above the mud motor which would be located directly above the mud motor. The ability to log torque, total RPM of drill bit 90, differential pressures, seal boot pressures, vibration, stick slip, and communicate with MWD tools positioned above mud motor 250 would further lessen any potential advantages RSS tools have over mud motors. A standard mud motor 130 or a downhole-adjustable mud motor (e.g., downhole-adjustable mud motor 250) with electronic logging (via electronics package 125) and/or downhole transmission (via electronics package 138) using a MWD tool positioned above the mud motor for telemetry could offer substantial cost savings relative to RSS tools offering similar functionality while providing additional data RSS systems typically cannot supply such as total torque output.
Referring to
In some embodiments, sensors placed in bend adjustment assembly 505 may indicate the bend setting of mud motor 500 so the operator would know electronically what position the mud motor 500 is in. In the embodiment of
The oil reservoir health for bend adjustment assembly 505 could also be checked using pressure sensors, LVDT, and proximity sensors of sensor packages 504 to determine the location of compensating piston 356 relative to the upper offset housing 360. If compensating piston 356 came into contact with the proximity sensor of the upper sensor package 504 of housing 360, the upper sensor package 504 would indicate that bend adjustment assembly 505 had lost oil during operation. If the pressure in this section was equal to the well bore pressure the user would also know the seals and oil bath had been compromised in this section of mud motor 500. Placing sensor packages 504 in upper offset housing 360 would cover both a “straight-to-bent” two-position configuration of mud motor 500 as well as a three position configuration of mud motor 500.
In this embodiment, the sensor packages 504 of actuator housing 340 (shown in
As shown particularly in
As shown in
In some embodiments, torque and oscillation or acceleration measurements alternatively could be measured by an electronics package (e.g., electronics package 125 or 138) or pressure, force, and/or vibration sensor in driveshaft adapter 120. The data collected by the electronics package (e.g., electronics package 125 or 138) could be relayed via a short a hop device mounted inside the driveshaft adapter (e.g., via electronics package 138 disposed in driveshaft adapter 132) to the MWD tool positioned directly above the mud motor (e.g., mud motors 250, 505) and then pumped to the surface of borehole 16. By collecting the pressure, oscillation or acceleration in Gs, and the torque output data and setting minimum threshold values for the pressure, vibration, and torque measurements seen at driveshaft adapter 120 and short hopping this collected information to a MWD tool a “yes” or “no” on oscillation and locker assembly function could be determined for the mud motor. This is beneficial as the position of the mud motor's bend setting (e.g., the unbent and bent positions), oscillation frequency and magnitude, oil reservoir heath and locker assembly health could all be checked with only a wire and sensors passed between the upper offset housing 360 and the driveshaft housing 104″, as shown in
In some embodiments, the remaining electrical components would all be inside the driveshaft adapter 120 or 132 and the rotor of the power-section of mud motor 500 making packaging more convenient. Putting all the sensors, batteries and wires where they terminate in or above the upper offset housing provides a large cross sectional area in the downhole adjustable motor to place the sensors needed for the motor position sensors and internal pressure. Such a configuration would make wiring mud motor 500 less cumbersome as far as fitting sensors (e.g., sensors 504, 506, 508, and 510, etc.), batteries and wires in the assembly without the need for slip rings between the rotating components of bearing assembly 200 and bend adjustment assembly 505. This would aid reliability.
Referring to
An embodiment of actuating mud motor 605 via hydraulic pumps 660 is described herein, which may occur on or off bottom of borehole 16 while drilling. In this embodiment, mud motor 605 includes one or more first or upper hydraulic pumps 660A (shown in
The trigger to actuate mud motor 605 could be provided from a rotary downlink similar to the downlinks described in U.S. Pat. No. 9,488,045, or by pushing a button at the surface of borehole 16. The operation of the following procedure could also be triggered by a rotational rate or RPM threshold or a combination of RPM, flowrate, and/or pressure thresholds of mud motor 605 as well. Particularly, in some embodiments, when mud motor 605 is sliding along sidewall 19 of borehole 16 or the rotational rate of driveshaft 106 and bearing mandrel 202 below 10 RPM (average), bend adjustment assembly 610 of mud motor 605 is configured to shift to the bent position, and when driveshaft 106 and bearing mandrel 202 are rotating at a rotational rate of 30 RPM or greater, bend adjustment assembly 610 of mud motor 605 is configured to automatically actuate to the unbent position 303. In this embodiment, the actuation of mud motor 605 to the unbent position 303 is initiated by upper hydraulic pumps 660A on the low pressure side of lock piston 380, which equalizes the pressure on both sides of lock piston 380 (indicated by arrows 662 of the exhaust (high pressure) and intake (low pressure) flows in
In some embodiments, biasing member 354 for actuating compensating piston 356 may not be required if the compensating piston 356 is pressured up on the low pressure side by a second hydraulic pump 682 to return the lock piston 380 to the lower furthest downhole unlocked position instead of using a spring, as shown in the embodiment of a mud motor 700 shown in
In some embodiments, if shifting mud motor 605 from the unbent position to a bent position or a low bend position to a high bend position the order of operations or series of events includes: the shifting process would start by upper hydraulic pumps 660A on the low pressure side of the lock piston 380 would begin to equalize the pressure on both sides of the lock piston 380, as shown in
Once engaged the locker assembly of mud motor 605 pulls the bend adjustment assembly 610 into the bent position using torque from power section 652 of mud motor 605. Sensors in the adjustable section may detect the tool had reached the fully bent position. At this point the upper hydraulic pump 660A positioned proximal lock piston 380 will reverse flow and start to decrease the pressure on the uphole side of the lock piston 380 and allow the lock piston 380 to re-engage into the locked position for drilling ahead. Once the lock piston 380 has started to engage and lock, the lower hydraulic pump 660B disposed proximal actuator piston 402 reverses flow direction to lower the pressure on the uphole side of actuator piston 402 and allow the actuator piston 402 to fully disengage thus completing the shifting cycle to the bent position. In this embodiment, hydraulic pumps 660A, 660B each include a controller or processor comprising a memory that stores a setpoint configured to control the actuation of hydraulic pumps 660A, 660B. In this embodiment, hydraulic pumps 660A, 660B are in signal communication with one or more of sensor packages 504, 506, 508, and/or 510 to receive signals corresponding to rotational rate of driveshaft 106 and bearing mandrel 202, fluid pressure within mud motor 605, and/or fluid flow rate in mud motor 605.
By adding these hydraulic pumps 660A, 660B and by using WDP joints the operation of mud motor 605 may be accomplished by pushing a button at the surface of the borehole 16 and waiting for mud motor 605 to shift and send the pressure signal or the electronic sensor confirmation that it had shifted. Secondly, mud motor 605 may be shifted, with the shifting of mud motor 605 being confirmed electronically via one of the sensing methods described above. By adding hydraulic pumps 660 and sensors (e.g., sensors 304, 306, and 508, etc.) the operation of mud motor 605 may be automated and greatly simplified. The ability to shift or adjust the bend setting of mud motor 605 remotely without special operations or changes in flowrate to drill bit 90 may allow many other fully automated drilling tools to control mud motor 605 without the operator on surface having to worry about adjusting pumps or picking up off bottom to shift. Additionally, the use of these items would negate having to follow the startup sequences at each connection or when the pump goes down while drilling.
Referring to
This configuration allow electronics to actuate solenoid valves 752 between a closed position restricting fluid flow through ports 368 and an open position permitting fluid flow through ports 368 in response to adjusting the RPM of driveshaft 106 via the same downlinking method described in U.S. Pat. No. 9,488,045, which is incorporated herein by reference for all of its teachings. For example, a memory of the electronics package of each solenoid valve 752 may include an RPM setpoint and a controller configured to shift solenoid valve 752 between open and closed positions in response to an RPM sensor of solenoid valve assembly 752 sensing driveshaft 106 rotating at the RPM setpoint. Additionally, the electronics package of each solenoid valve 752 may include a flowrate setpoint of fluid flowing to mud motor 750, and in response to sensing fluid flowing through mud motor 750 at the setpoint via a flow sensor of mud motor 750, the controller is configured to shift solenoid valve 752 between open and closed positions.
Alternatively, in other embodiments, solenoid valves 752 are actuated by a signal sent along wired drill pipe connections 502 and coils 500. In some embodiments, the operation of the locking feature provided by solenoid valves 752 includes: solenoid valves 752 are initially in the open position, allowing an operator of well system 10 to actuate bend adjustment assembly 755 to a desired position (e.g., the unbent position, bent position, etc.). Once an operational flowrate is established to mud motor 750, locking piston 380 is actuated to the locked position. A signal is then passed via flowrate changes to mud motor 750 and/or RPM changes of driveshaft 106 from surface (as described in U.S. Pat. No. 9,488,045), or a signal from surface via wired drill pipe connections 500, 502 to the electronics board and solenoid valves 752 to not allow flow across ports 368 of upper adjustment mandrel 360. Once flow is blocked off across ports 368, locking piston 380 cannot be returned to the unlocked position by the biasing force supplied to compensating piston 356 by biasing member 354.
The closing of solenoid valve 752 effectively locks bend adjustment assembly 755 from shifting to a reset or alternate bend setting until solenoid valves 752 are actuated into the open position, permitting fluid flow across ports 368 of upper adjustment mandrel 360. Thus, the operator of well system 10 is permitted to shut off surface pump 23, ceasing fluid flow to mud motor 750, while still maintaining bend adjustment assembly 755 in its current bend position. When the operator of well system desires to change the bend position of bend adjustment assembly 755, the operator may disable the locking feature by sending a first or opening signal to solenoid valves 752 to actuate them into the open position permitting fluid flow through ports 368 of upper adjustment mandrel 360. Once fluid flow is permitted through ports 360, the operator of well system 10 may mechanically shift bend adjustment assembly 755 to an alternate bend position. Once the operator has reached the alternate bend position of bend adjustment assembly 755 and the drilling flowrate is provided to mud motor 750 by surface pump 23, a second or closing signal is transmitted to solenoid valves 752 to actuate valves 752 into the closed position preventing fluid flow through ports 368 and locking bend adjustment assembly into the alternate bend position. In this embodiment, solenoid valves 752 are configured to actuate into the open position in the event of a failure to supply electrical power to valves 752, permitting the operator of well system 10 mechanically shift bend adjustment assembly 755 as described above.
In some embodiments, the signal to open and close solenoid valves 752 is triggered by fluid pressure within the central passage of upper adjustment mandrel 360, as sensed by a pressure sensor in signal communication with solenoid valves 752. This way the operator of well system 10 could flow fluid to mud motor 750 at a high flowrate to generate this high pressure to lock and unlock the tool by closing and opening solenoid valves 752, and then reduce the flowrate supplied to mud motor 750 to an operational or drilling flowrate. Additionally, in this embodiment only upper adjustment mandrel 360 need include electronics (solenoid valves 752) in order to permit the electrically actuated locking of bend adjustment assembly 755, where upper adjustment mandrel 360 has a relatively large cross section to place package electronics, batteries, and wires, etc., therein compared to other components of bend adjustment assembly 755. In other embodiments, solenoid valves 752 may be positioned in lower offset housing 320 for selectably permitting and restricting fluid flow through ports 330 thereof to thereby lock and unlock bend adjustment assembly 755.
While exemplary embodiments have been shown and described, modifications thereof can be made by one skilled in the art without departing from the scope or teachings herein. The embodiments described herein are exemplary only and are not limiting. Many variations and modifications of the systems, apparatus, and processes described herein are possible and are within the scope of the disclosure presented herein. For example, the relative dimensions of various parts, the materials from which the various parts are made, and other parameters can be varied. Accordingly, the scope of protection is not limited to the embodiments described herein, but is only limited by the claims that follow, the scope of which shall include all equivalents of the subject matter of the claims. Unless expressly stated otherwise, the steps in a method claim may be performed in any order. The recitation of identifiers such as (a), (b), (c) or (1), (2), (3) before steps in a method claim are not intended to and do not specify a particular order to the steps, but rather are used to simplify subsequent reference to such steps.
This application is a continuation of U.S. non-provisional patent application No. 16,398,177 filed Apr. 29, 2019, and entitled “Wired Downhole Adjustable Mud Motors,” which claims benefit of U.S. provisional patent application Ser. No. 62/663,669 filed Apr. 27, 2018, and entitled “Wired Downhole Adjustable Mud Motors,” both of which are hereby incorporated herein by reference in their entirety.
Number | Date | Country | |
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62663669 | Apr 2018 | US |
Number | Date | Country | |
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Parent | 16398177 | Apr 2019 | US |
Child | 17480319 | US |