This invention relates to the field of top drives and in particular to a top drive accessory, referred to herein as an integrated casing drive, which may form part of a system which includes a top drive having a slewing pipe handler and tubular gripper.
At least three top drive manufacturers and at least two third-parties offer a top drive accessory known as a Casing Running Tool (herein a CRT). CRT's attach, directly or indirectly, to the top drive quill and enable the top drive (hereinafter also referred to as a “TD”) to hoist, rotate and circulate casing without screwing into it, which is advantageous as explained below. A CRT grips and seals either on the outside or the inside of the casing.
In the prior art, applicant is aware of: Tesco™ U.S. Pat. Nos. 7,140,443 and 7,377,324, and Tesco's related products; National Oilfield Volant™ (NOV) U.S. Pat. Nos. 6,443,241 and 7,096,977, and NOV's related products; Canrig™ U.S. Pat. No. 7,350,586 and Canrig's related products; Weatherford™ U.S. Pat. No. 7,191,840 and Weatherford's related products.
Basic casing operations are similar with or without the use of a top drive. Slip-type elevators are generally required to hoist more than 200 tons casing string weight. In conventional casing running operations, the traveling equipment (TD or not) only hoists the casing, with no rotational capability. Rotation for make-up is provided by a casing tong at the floor. An internally sealing packer (e.g. a Tam Packer™) may be installed on the TD quill to selectively seal inside the casing to facilitate circulation. Conventional casing running operations can only make up a casing joint; there is no capability to rotate the casing string.
Casing adaptor nubbins have been used to rotate and/or circulate casing with top drives. These are simple crossovers between the TD quill (or drillstem valve or sub) and the upper casing connection. They allow the top drive to screw into the top of the casing approximately like any drilling tubular. But it is a serious disadvantage to screw into the casing because the well owners do not want to risk any damage to the sensitive casing threads because it could compromise the integrity of the well.
The reasons well owners wish to rotate and circulate casing with the TD are known to those skilled in the art and are well covered in the CRT prior art references above, and are incorporated herein by reference.
The CRT's work reasonably well but have the following drawbacks:
Top Drives may advantageously include a rotatable pipe handler section which includes: a gripper capable of clamping tubulars immediately below the TD (also called wrenches, back-up wrenches and grabbers by the various manufacturers); and, elevator links supported by structural elements capable of transmitting the elevator load directly or indirectly to the hoisting equipment (typically a traveling block).
Most top drives of which applicant is aware in the relevant class have rotatable pipe handlers for the primary purpose of actuation of the corresponding link-tilt in any plan-view orientation.
A rotatable pipe handler normally has a static or stator section anchored to the TD frame and a rotatable or rotor section containing or mounted to the elevators, elevator links and supporting structure, the link tilt actuator and the gripper. The rotatable section is typically guided on the static section by a rolling-element slewing bearing or by bushings. The rotatable pipe handlers of which applicant is aware have a capability to rotationally lock the rotatable section to the static section or the TD frame using a pipe handler lock. The pipe handler lock may include pins, tooth-engaged locks and self-locking worm gears. The locks may or may not be remotely controlled.
Many of the rotatable pipe handlers have an independently powered rotation capability, remotely controlled from the operator's station, for the pipe handler rotate function. The pipe handler rotate function typically turns the pipe handler slowly (5-10 RPM) and with very limited torque capacity (2000-3000 ft-lb max). Most of such conventional rotatable pipe handlers have a fluid rotary union (also known as rotary manifold) to transmit for example hydraulic energy (which is most common) from the static section to the rotatable section for actuation of the link tilt, gripper, etc. Elevator hoisting loads (axial) are either transmitted from the rotatable section to the static section via a thrust bearing or bushing or are transmitted from the rotatable section to the TD main shaft (quill or spindle) via a load shoulder.
The integrated casing drive, herein also referred to as an ICD, according to the present specification allows a top drive to transmit rotational energy to tubulars, such as casing without screwing into the casing, for the purposes of: making up the casing, rotating the casing string while running it into the hole, rotating the casing string during cementing, and casing drilling. As used herein, the term, casing, is intended to include other forms of tubulars.
The integrated casing drive according to one aspect provides a means to selectively connect the gripper to the primary or main rotary drive of the TD for the purpose of rotating a casing or other tubular. The gripper clamps near the top end of the casing or other tubular and can then rotate the casing or other tubular without screwing into the top of the casing or other tubular.
The present invention ICD works in conjunction with a top drive having a main shaft or quill rotary drive and a rotary union thereunder from which depends a selectively rotatable pipe handler having a gripper. As used herein, the phrase: “rotatable energy coupling” (herein also REC) is defined to mean any one of the following that transfers energy across a rotating coupling for powering the pipe handler gripper, etc, including but not limited to: fluid (eg. hydraulic, pneumatic) rotary union or rotary manifold, electric slip ring, or inductive coupling, or advantageously as described in applicant's U.S. patent application Ser. No. 13/669,419, publication no. 2013/0055858, referred to herein and incorporated by reference.
The ICD may be characterized in one aspect as including a selectively releasable ICD lock (for example, akin to a pipe handler lock) for locking the rotation of the pipe handler to the rotation of the main shaft or quill or corresponding main rotary drive in the top drive (herein collectively referred to as the top drive rotary drive portion) to thereby simultaneously rotate a length of casing held in the gripper with driven rotation of the rotary drive portion, without a threaded connection being made between the top drive quill and the length of casing.
In a first embodiment, not intended to be limiting, the conversion of the stator between its normal rigidly fixed mode, rigidly fixed to the top drive frame, within which frame a main drive sprocket is rotated by top drive motor(s) mounted on the frame, and its integrated casing drive mode wherein the stator is unlocked from the top drive frame and instead locked to, for rotation with, the main drive sprocket, is accomplished using a mode-shift mechanism (MSM). An ICD locking assembly may in one embodiment form part of the MSM, so that, in a drive sense it functions to lock, the stator and the main drive sprocket. The ICD locking assembly locks to the stator and is unlocked from the main drive sprocket for normal operation of the REC, and is unlocked from the stator and locked to the main drive sprocket for engaging the integrated casing drive.
In the locked or normal operation mode, the stator is thus fixed to, so as to form part of the fixed portion of the REC. The REC works to transfer energy between the fixed and rotating components while allowing rotation of the pipe handler. In the integrated casing drive mode, the stator is fixed to the main drive sprocket for rotation therewith and unlocked from the fixed portion of the REC, and so, in fact, is no longer a stator at all. Thus rotation of the main drive sprocket directly rotates the pipe handler and its gripper. The locking of the stator to the main drive sprocket may be provided by using merely bushings or bearings or the like which normally allow the pipe handler to rotate, and then using a suitable lock such as an ICD lock (also referred to herein as a casing drive lock) of the kind described herein, or as otherwise would be known to one skilled in the art to provide the requisite locking function, or for example such as a pipe handler lock, or for example using locking members as would be known to one skilled in the art such as pins, shafts, locking dogs, teeth-engaging segments, or other lock members to lock the stator to the main drive sprocket.
In one embodiment, not intended to be limiting, the locking assembly is mounted on, for example, an ICD plate as described below, and the lock may be a shuttle lock of the form wherein a pin or other elongate rigid member (collectively referred to herein as a pin) which is biased by a pin actuator for translation between for example raised and lowered positions, so as to lock the REC when the pin is in its ICD mode for the operation of the integrated casing drive.
In one embodiment, not intended to be limiting, the lock actuator may be an actuating shaft, or threaded jacking screw in threaded engagement with the lock member. A plurality of lock members may be provided. Manual or automated actuators may be provided. Stops may be provided to limit translation of the lock members. The translation of the lock members may be vertical, although again this is not intended to be limiting as other orientations of the lock members would work.
Advantageously a sensor such as a proximity sensor is provided to detect and confirm the positioning of the locking members into the locking member's normal or ICD mode position.
In a second embodiment, the mode shift mechanism includes a selectively engageable casing drive lock engageable between the rotor and the rotary drive portion directly, so as to lock rotation of the rotor relative to the rotary drive portion when the mode shift mechanism is in the casing-drive mode.
The casing-drive lock may include a locking member positionable and actuable to engage the rotary drive portion. The rotary drive portion may have at least one aperture, and the locking member is actuable to engage in the aperture when the mode shift mechanism is in its casing drive mode.
In view of the two embodiments provided by way of example herein, the present invention may in one aspect be summarized as an integrated casing drive system and a method for making, assembling or using same, which includes a top drive having a rotary drive portion, a pipe handler having a casing gripper wherein the pipe handler is rotationally mounted to the top drive, and a selectively actuable casing drive lock for locking the rotary drive portion.
An integrated casing drive system combines a top drive having a rotary drive portion driving rotation of a drill string engagement piece, a pipe handler having a gripper wherein the pipe handler is rotationally mounted to the top drive, and a selectively actuable casing drive lock for locking the rotary drive portion to the pipe handler.
The integrated casing drive (herein also referred to as an “ICD”) according to one embodiment which is not intended to be limiting, cooperates with a top drive (TD) and includes a mode-shift mechanism (MSM) such as for example the ICD plate 10 of
The MSM includes locking members as herein broadly defined. In
In ICD mode, that is with ICD plate 10 locked to main sprocket 12, rotation of main sprocket 12 by the top drive motor(s), for example drive motors 40 seen in
In the illustrated embodiment of
A proximity sensor 32 may be provided to positively detect when the pins 16 are lowered into their normal mode, i.e., the normal mode of operation of the top drive.
A slewing bearing 34 may be mounted between ICD plate 10 and stator 14. ICD plate 10 may be mounted to slewing bearing 34 and slewing drive 18 by means of bolts 36. Stator 14 may be mounted to slewing bearing 34 by means of bolts 38.
The casing tubular or casing string is hoisted via the normal elevator and link system. Either slip-type or collar-type elevators may be used. The elevator link tilt actuators are not shown.
Slewing bearing 34 selectively allows the normally (i.e., in normal mode) static section, stator 14, of the pipe handler to turn relative to the frame of the TD.
For normal operations, locking pins 16 rotationally connect the normally static section, stator 14, of the pipe handler to the frame of the top drive. This is functionally identical to a conventional rotatable pipe handler, and operates in what is referred to herein as its normal mode.
For casing operations (ie, in ICD Mode), the ICD pins 16 are shifted up to connect the normally static section, stator 14, of the pipe handler to the TD main drive sprocket 12. Pins 16, or other lock members, may also lock to a bull gear on a gear-driven machine, or alternatively directly to other components of the rotary drive portion. Rotational energy can then be transmitted from the TD main drive, for example via sprocket 12, to pipe handler 22 via the ICD pins 16 (or such other locking members as may be employed).
Although only two ICD pins 16 are shown, any number could work. One could also use any type of clutch (e.g. without intending to be limiting a disk or drum) actuated by means known to one skilled in the art (e.g. manual, pneumatic, hydraulic, electric). It is intended that reference herein to a lock or lock member or locking member is intended to include locks, latches, clutches, or other means known in the art to effectively mate the rotor into its ICD mode so as to rotate simultaneously with rotation of the rotary drive portion of the TD.
Note that in
The gripper 24 may be actuated to clamp the casing tubular so that it turns with the pipe handler.
The elevators which co-operate with the TD such as shown in
Rotary power for casing operations is theoretically limited only by the drive capacity of the TD (1000 horsepower (HP) typical) but would normally be restricted to the order of 30 RPM and the maximum make-up torque of the casing (typically <20,000 ft-lb).
The gripper has axial float capability to accommodate casing thread advance and axial deflections under hoisting loads. An internally sealing conventional packer (e.g. a Tam Packer™); may be used to facilitate circulation. The casing size is limited to the gripper maximum opening diameter, for example 9⅝ inch casing. An auxiliary casing gripper may be provided for any larger casing sizes.
Torque instrumentation is provided by the normal top drive rotary drive system. The system may also include an optional load cell, which may be mounted at the pipe handler lock, or the functional equivalent to measure the reaction between the static and rotatable sections of the pipe handler.
Incorporated by reference herein is applicant's U.S. patent application Ser. No. 13/669,419 entitled “Top Drive With Slewing Power Transmission” filed Nov. 5, 2012, and published 7 Mar. 2013 under publication number 2013/0055858. That application discloses an REC of a type referred to herein as an SPT coupling. The description of such SPT couplings are incorporated herein by reference, and in any event, as now published, are taken to have been reviewed and understood by those skilled in the art. Such a Slewing Power Transmission is advantageous for the Integrated Casing Drive if it avoids the disadvantages of fluid rotary unions typical of most other rotatable pipe handlers. Typical fluid rotary unions present the following challenges:
Note that the rotary unions are disadvantageous but may work for an integrated casing drive.
Similar functionality may also be achieved by coupling the rotatable section of the Pipe Handler to the main shaft of the TD (spindle or quill) so that the rotatable section is driven by the TD motors, and using the best available rotary union seal technology, restrict rotary speeds as required. Unload grip pressure at the rotary union once the gripper is clamped. Apply an empirical correction to the torque instrumentation to account for rotary union friction.
For the above described embodiment employing ICD plate 10,
A second embodiment of the invention employs a spur gear for pipe handler rotation and ICD locking members on the rotor which lock to the rotary drive portion in the ICD mode of the MSM. As seen in
As before, main sprocket 12 is driven by the top drive drive motors 40 so as to conventionally drive the rotation of spindle 26. In the illustrated embodiment, main sprocket 12 is driven by a plurality of drive motors 40 and corresponding gear reducers, mounted on drive plate 42. Drive plate 42 forms part of the top drive frame. Two drive motors 40 are illustrated, it being understood that in the illustrated embodiment, four such drive motors 40 and the corresponding gear reducers may be mounted on drive frame plate 42. Drive motors 40 and the corresponding gear reducers, drive the rotation of the corresponding main drive gears 44 so as to drive the rotation of main sprocket 12 for example by means of a drive belt (not shown).
Stator 14 is mounted underneath drive sprocket 12. Stator 14 is rigidly mounted to the top drive frame. At least two rigid bridge-pieces 46 are mounted between drive plate 42 and stator 14 so as to maintain stator 14 rigidly parallel with and spaced from top drive plate 42. Thus a pair of bridge-pieces 46, such as in the illustrated embodiment, will maintain the positioning and alignment of stator 14 relative to top drive frame plate 42, thereby sandwiching main sprocket 12 for rotation therebetween.
Spur-gear 48 is rigidly mounted to rotor 20 for rotation therewith. Spur gear 48 and rotor 20 rotate about the longitudinally extending centre-line axis A of spindle 26. As before, conventionally pipe handler 22 includes gripper 24 and is mounted to rotor 20, although not shown in this illustrated embodiment. Thus in the normal mode of operation of the top drive and pipe handler, rotor 20 is rotated in direction B by the selective operation of at least one pinion gear 50.
Pinion gear 50 is driven by drive motor 52 via drive shaft 50a, which rotates drive shaft 54. Drive shaft 54 extends from drive motor 52, through bores in the corresponding bridge-piece 46, so as to engage its corresponding pinion gear 50. In the TD normal mode, pinion gear 50 selectively rotates rotor 20 and thereby also selectively rotates pipe handler 22 and gripper 24. When the TD is in ICD mode, pinion gear 50 is free-wheeling, or may be disengaged from its engagement with spur gear 48. A toothed locking segment, which may be characterized as a locking dog, is mounted to stator 14 and is actuable so as to engage spur gear 48. In the TD normal mode toothed locking segment 56 may be engaged, for example locked, with spur gear 48 or may be lowered or otherwise disengaged so as to be out of mating engagement with teeth 48a on spur-gear 48 for re-orienting of the pipe handler. By way of example, locking segment 56 may be actuated into, and out of, engagement with the teeth 48a of spur-gear 48, by an elongate actuating member such as a linearly driven shaft (not shown) or by a rotatably driven jack screw 58. Lock actuating jack screw 58 may be driven by a corresponding drive motor 60. Thus in the illustrated embodiment, locking segment 56 locks and unlocks from engagement with spur-gear 48 by being actuated in direction C, parallel to centreline axis A. In the illustrated embodiment which, again, is only intended to show one example of many mechanisms which may be employed to lock rotation of rotor 20, locking segment 56 is guided during its translation in direction C by guide dowels 62. In
In normal mode, locking segment 56 may be lowered and thereby unlocked from spur-gear 48, rotation of pipe handler 22 may be accomplished in the conventional fashion by the actuation of drive motor 52 driving pinion 50. Thus, in normal mode, rotation of pipe handler 22 may be accomplished independently of rotation of main sprocket 12 and its corresponding rotation of spindle 26.
When in ICD mode, rotor 20 is locked to spindle 26 by means of at least one ICD locking member 64, for example radial locking pins or shafts or shear beams which may include load bearing cells; for example commercially available load measurement transducers. Although it is understood that rotor 20 may be locked to any part of the rotary drive portion including the spindle, quill, main drive, sprocket, bull gear, or attachments thereto, in the illustrated embodiment each ICD locking member actuates radially inwardly and outwardly of centreline axis A through a corresponding aperture 26a in the sidewall of spindle 26. In the illustrated embodiment, again which is not is intended to be limiting, an oppositely radially disposed pair of locking members 64 lock and unlock from engagement with spindle 26 by translation radially of centreline axis A in direction D. In the illustrated example where the locking members 64 are shear beam load cells, the shear beam load cells translate relative to housings 66. Housings 66 are mounted to rotor 20. Thus in ICD mode, rotor 20 is locked to the rotation of spindle 26 by the manual, or remote, or automated actuation of locking members 64. Note that the load cell need not be in the locking device itself; but can be anywhere in the rotational transmission between the rotary drive portion and the rotor, and foreseeably anywhere between the rotary drive portion and the gripper.
In this embodiment stator 14 is fixed to the TD frame at all times. A slewing bearing allows rotation of the rotor plate 20 relative to the stator plate 14 (i.e. Rz as conventionally defined is free) but fixes the rotor plate 20 to the stator plate 14 with respect to the other five degrees of freedom as conventionally defined (X, Y, Rx, Ry). The slewing bearing may for example be a Kaydon Bearings™ Model RK6, which is a ball bearing design. The inner race is fixed to the stator plate. The outer race is fixed to the rotor. The outer race is geared, for active pipe handler rotation for example by motor 52 and pinion 50 mounted on the TD frame or stator plate.
Variations on the use of the slewing bearings may include: roller bearing or dry sliding bearing, double/triple/quad bearing, sealed or not, outer fixed to stator, inner fixed to rotor, internally geared, not geared at all (could have no handler rotate function), separate gear fixed to either race, handler rotate motor/pinion mounted on the pipe handler, rotor could be rotationally mounted to the spindle/quill instead of to the rotor.
The rotor is the mounting platform for the rotatable pipe handler, and is fixed to the outer race of the slewing bearing (or could be inverted; as per the above variations).
Other optional pipe handler rotate motor/pinion arrangements may include:
The pipe handler lock may be an internally toothed locking dog or segment 56 mounted to the stator wherein segment 56 may be axially displaced to selectively engage the spur-gear 48 in the slewing bearing. It may be actuated by a screw 58 driven by an electric motor 60 with a gear reducer, mounted on the TD frame/stator (42,14). Two may be preferred for redundancy and symmetry; but there could be any number as constrained by available space, and they could be in any plan-view orientation. Actuation could be hydraulic, pneumatic, etc or even manual.
Each preferably has a sensor to verify the proper locked position, for example a limit switch or proximity sensor. The ICD lock mechanism of the MSM could also be mounted/actuated on the rotor so as to lock against the stator. There exist many possible variations: pin(s) in a vertical axis engaging the rotor and stator (or extensions of same); pin(s) in a horizontal axis engaging the rotor and stator (or extensions of same); pins(s) of any shape in any other orientation engaging the rotor and stator (or extensions of same); bolted connection (bolts in any orientation); jaw clutch; plate clutch; drum clutch; a selectively engageable spline (spline can be any polygon, ie, not a circle); a wedge or cam lock; an indirect lock, eg, lock pinion which is geared (or chained or belted) to the rotor stator.
The ICD lock may include pins mounted to the rotor which may be selectively radially or otherwise displaced to engage the rotary drive portion. The rotor and pipe handler are thereby rotationally coupled to the rotary drive portion of the TD.
A pair of ICD locks may be used for load balance; but there could be any number as constrained by available space. The pins may be shear beam load cells to measure the ICD torque. Actuation may be manual or remote controlled (e.g. hydraulic, electric, pneumatic). The ICD lock could engage anything attached to the rotary drive portion, e.g. the spindle, quill, main drive sprocket or bull gear. There are many possible variations, again including: Pin(s) in a vertical axis engaging the bull gear or sprocket; Pin(s) in a horizontal axis engaging the spindle or quill; Pin(s) of any shape in any other orientation engaging the rotary drive portion; Bolted connection (bolts in any orientation); Jaw clutch; Plate clutch; Drum clutch; A selectively engageable spline (spline can be any polygon, ie, not a circle); A wedge or cam lock; An indirect lock, eg, lock a pinion which is geared (or chained or belted) to the rotary drive portion; Other load cell types and mounting configurations.
Actuations of the ICD lock is manual in the basic case. An operator pushes the locking member (pin, shaft, load cell) in and out of ICD mode by hand, and may install a pin, latch or other retainer in either position. A screw could be used for manual actuation.
Remote controlled actuation is optional, by hydraulic or pneumatic cylinder electric actuator, etc. A cylinder and rod may connect between the load cell pin and an angle, block, or housing 66 on the rotor plate.
The use of load cells is optional as one could rely entirely on the TD's torque instrumentation.
To summarize, and as may be determined from viewing
Disconnecting pinion 50 from spur gear 48 may be advisable when in ICD mode as the back-drive speed of the pinion may exceed the limits of the reducer and/or the motor. For example operating the ICD at 20 RPM may equate to 20,000 RPM or more at the pipe handler rotate (HR) motor. Further, the frictional resistance of the motor(s) and reducer(s) may distort the torque measurement from any load cells. Consequently, one embodiment includes provisions to de-couple between the pinion and the motor's gear reducer when in ICD mode. For example a female spline coupling may be used to vertically disengage the pinion shaft. A spring may be used to hold the female spline coupling down in the normal working position and help re-engage if the spline teeth are not initially aligned.
Alternatively, any of the pinion 50, the HR motor, the HR reducer, or the HR connecting shaft may be entirely removed when in ICD mode to accomplish the HR de-coupling.
Disconnecting pinion 50 may not be needed if larger HR motors are used so the reducer ratio may be lower, or if lower HR torque in normal operations is acceptable, or if the maximum ICD speed is reduced, or if the frictional resistance of the HR motors and reducers is approximately constant, so one could offset for it in the ICD torque calculation. For example, using two ¾ HP handler rotate motors, a 43.3:1 reducer ratio, 15 RPM maximum (max) ICD speed, 1839 ft-lb max HR torque, then the max ICD backdrive motor speed would be 4203 RPM, which would likely be acceptable.
As will be apparent to those skilled in the art in the light of the foregoing disclosure, many alterations and modifications are possible in the practice of this invention without departing from the spirit or scope thereof. Accordingly, the scope of the invention is to be construed in accordance with the substance defined by the following claims.
This application is a continuation of U.S. patent application Ser. No. 14/064,103 filed 25 Oct. 2013, which claims priority to U.S. provisional patent application No. 61/718,284 filed 25 Oct. 2012, entitled Integrated Casing Drive.
Number | Date | Country | |
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61718284 | Oct 2012 | US |
Number | Date | Country | |
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Parent | 14064103 | Oct 2013 | US |
Child | 15717726 | US |