This application is a U.S. national stage patent application of International Patent Application No. PCT/US2015/039537, filed on Jul. 8, 2015, the benefit of which is claimed and the disclosure of which is incorporated herein by reference in its entirety.
The present disclosure relates generally to oilfield equipment, and in particular to downhole tools, drilling systems, and drilling techniques for drilling wellbores in the earth. More particularly still, the present disclosure relates to a method and system for improving the rate of penetration of a drill bit.
Down hole drilling units are frequently used for multiple purposes, such as drilling through virgin formation, cleaning a wellbore, drilling through cement plugs, etc. Depending on the task at hand, such downhole drilling units be run on drill strings, wireline cable, or coiled tubing, for example. The cost to drill or service a wellbore may be determined in large part by the effective rate of penetration during drilling operations. Traditional rotating drill bits are useful for shearing and removing weak materials. As well depth increases, formation rock strength may increase, and the mechanical limitations of the drilling string and the drill bits may result in decreased rate of penetration. Similarly, drilling through cement plugs or other downhole tools may result in a low rate of penetration.
Downhole tools that impart axial impact forces to a drill bit may increase rock cutting efficiency while simultaneously reducing the required rock cutting force. Reducing cutting force may result in lower drill bit wear and breakage, less frequently encountered stick-slip conditions, lower probability of shearing the drill string, and a concomitant greater effective rate of penetration. Downhole impact tools that create axial impact forces using a hydraulic flow of drilling fluid that actuate a complex system of valves and pistons may not be particularly optimal for all drilling operations, particularly those operations conventionally performed using wireline or coiled tubing systems.
Embodiments are described in detail hereinafter with reference to the accompanying figures, in which:
The present disclosure may repeat reference numerals and/or letters in the various examples. This repetition is for the purpose of simplicity and clarity and does not in itself dictate a relationship between the various embodiments and/or configurations discussed. Further, spatially relative terms, such as “beneath,” “below,” “lower,” “above,” “upper,” “uphole,” “downhole,” “upstream,” “downstream,” and the like, may be used herein for ease of description to describe one element or feature's relationship to another element(s) or feature(s) as illustrated in the figures. The spatially relative terms are intended to encompass different orientations of the apparatus in use or operation in addition to the orientation depicted in the figures.
In the disclosure, like numerals may be employed to designate like parts throughout. Various items of equipment, such as fasteners, fittings, etc., may be omitted to simplify the description. However, routineers in the art will realize that such conventional equipment can be employed as desired.
Wireline or coiled tubing system 10 may include a sheave or arcuate rail 25 for guiding the conveyance 11 into wellbore 13. Conveyance 11 may be spooled on a reel 26 storage. Conveyance 11 carries downhole tool assembly 12 and is payed out or taken in to raise and lower downhole tool assembly 12 within wellbore 13, as desired.
In the case of a wireline system, conveyance 11 may be a wireline cable. Electrical conductors within cable 11 may operatively connect downhole tool assembly 12 with surface-located equipment, which may include an electrical power source 27 to provide power to downhole tool assembly 12. Cable 11 may also include electrical conductors and/or optical fibers to provide communications between downhole tool assembly 12 and a communications module 28 at the surface of wellbore 13. In the case of a coiled tubing system, conveyance 11 may be a coiled tubing. Power and communication to downhole tool assembly 12 may be provided by a flow of drilling fluid through the interior of coiled tubing 11, in a manner similar to that of drilling system 22 of
According to one or more embodiments, downhole tool assembly 12 may include a mechanical percussive hammer assembly 100, which may rotate and apply repetitive axial impact forces to a distal bit 19, which may be a conventional drill bit, reamer, coring bit, or other suitable tool. Downhole tool assembly 12 may be used, among other purposes, to clean scale 70 or other undesirable accumulation from wellbore 13 and to drill through and clear various plugs or packers 72, such as fracturing and cementing plugs, during well intervention operations.
Downhole tool assembly 12 may also include a motor 18 operable to rotate distal bit 19 and provide mechanical power to percussive hammer assembly 100. A tractor assembly or anchoring device 17 may be provided within downhole tool assembly 12 for counteracting any tendency of downhole tool assembly 12 to rotate within wellbore 13 during rotation of distal bit 19. Tractor assembly or anchoring device 17 may be optional for coiled tubing use but may be generally required for wireline use, because of an inherent inability to effectively push tools with wireline cable. Finally, although not expressly illustrated, downhole tool assembly 12 may include various logging tools, which may generate data useful in analysis of wellbore 13 or in determining the nature of the formation 21 in which wellbore 13 is located.
In the case of a wireline system 10, motor 18 may be an electric motor. Downhole tool assembly 12 may also include a power supply assembly 15 for converting power from surface power source 27 to a suitable form for use by downhole tool assembly 12 and a downhole communications module 16 for maintaining communications with a surface communications module 28. In the case of a coiled tubing system 10, motor 18 may be a hydraulic motor or an electric motor powered by hydraulically-powered electrical generator. Downhole communications module 16 may be adapted for communications via mud pulse telemetry or the like.
Drilling system 22 may include a drilling rig 23. Drilling rig 23 may be located generally above a well head 24, which in the case of an offshore location is located at the sea bed and may be connected to drilling rig 23 via a riser (not illustrated). Drilling rig 23 may include a top drive 42, rotary table 38, hoist assembly 40 and other equipment associated with raising, lowering, and rotating a drill string 32 within wellbore 13. Blow out preventers (not expressly shown) and other equipment associated with drilling a wellbore 13 may also be provided at well head 24.
Drill string 32 may be assembled from individual lengths of drill pipe, coiled tubing, or other tubular goods. In one or more embodiments, drill string 32 has a hollow interior 33. An annulus 66 is formed between the exterior of drill string 32 and the inside diameter of wellbore 13. The downhole end of drill string 32 may carry a bottom hole assembly 52. Bottom hole assembly 52 may include percussive hammer assembly 100, which may rotate and repetitively apply axial impact forces to distal bit 19. Distal bit 19 may be a conventional drill bit, reamer, coring bit, or other suitable tool. Bottom hole assembly 52 may include a mud motor 58, operable to rotate distal bit 19 and provide mechanical power to percussive hammer assembly 100. However, an electric motor, powered by a hydraulically-powered electrical generator, for example, may be used in lieu of a mud motor. A tractor assembly or anchoring device 57 may be provided within bottom hole assembly 52 for counteracting any tendency of bottom hole assembly 52 to rotate within wellbore 13 during rotation of distal bit 19, particularly if drill string 32 includes coiled tubing. Bottom hole assembly 90 may also include various subs, centralizers, drill collars, logging tools, or similar equipment.
Various types of drilling fluids 46 may be pumped from reservoir 30 through pump 48 and conduit 34 to the upper end of drill string 32 extending from well head 24. The drilling fluid 46 may then flow through longitudinal bore 33 of drill string 32 and exit through nozzles (not illustrated) formed in distal bit 19 or elsewhere in bottom hole assembly 52. Drilling fluid 46 may mix with formation cuttings and other downhole fluids and debris proximate drill bit 92. Drilling fluid 46 will then flow upwardly through annulus 66 to return formation cuttings and other downhole debris to well head 24. Conduit 36 may return the drilling fluid to reservoir 30. Various types of screens, filters and/or centrifuges (not expressly shown) may be provided to remove formation cuttings and other downhole debris prior to returning drilling fluid to pit 30. Drilling fluid 46 may also provide a communications channel between bottom hole assembly 52 and the surface of wellbore 13, via mud pulse telemetry techniques, for example.
Downhole tool assembly 12 is carried by conveyance 11, which may be a wireline cable or coiled tubing, for example. A tractor assembly or anchoring device 17 may be provided within downhole tool assembly 12 for counteracting any tendency of downhole tool assembly 12 to rotate as distal bit 19 is rotated. Motor 18 may be an electric motor, powered via wireline cable, a hydraulic motor powered by fluid flow through coiled tubing, or an electric motor powered by a downhole hydraulically-powered electrical generator (not illustrated). Motor 18 may be connected to housing 110 by any suitable arrangement. For example, in the embodiment illustrated in
Bottom hole assembly 12 is carried by drill string 32, which may be assembled from individual lengths of drill pipe, coiled tubing, or other tubular goods, for example. A tractor assembly or anchoring device 17 (
According to one or more embodiments, percussive hammer assembly 100 may include a hammer 120, an anvil 130, and a drill body 140. A hammer spring 122 seated between upper end 111 of housing 110 and an upper end of hammer 120 urges hammer 120 in a downward direction against anvil 130. Similarly, an anvil spring 132 seated between a lower end 113 of housing 110 and a lower end of anvil 130 urges anvil 130 in an upward direction against hammer 120. Drill body 140 is rotatively captured within and drill 130 within anvil 130. The lower end of drill body 140 may have a connector 142 for receiving bit 19 (e.g.,
A circumferential portion of the inner surface of housing 110 has anvil spline grooves 134 formed therein. An outer circumferential portion of anvil 130 has corresponding anvil spline tabs 136 that are slidingly received within anvil spline grooves 134. Anvil spline grooves 134 and tabs 136 allow limited axial movement of anvil 130 within housing 110 but prevent rotation of anvil 130 with respect to housing 110.
A driveshaft 150 extends beyond upper end 111 of housing 110 for connection to a motor, for example electric motor 18 of tool assembly 12 (
Driveshaft 150 includes an upper spline 152 which is slidingly received within a complementary spline fitting formed within bore 124 of hammer 120. Accordingly, driveshaft 150 is operable to rotate hammer 120 while allowing hammer 120 to axially slide up and down about upper spline 152. Driveshaft 150 includes a lower spline 154 which is slidingly received within a complementary spline fitting formed within an upper portion of bore 144 of drill body 140. Accordingly, driveshaft is operable to rotate drill body 140 while allowing the drill body 140 and anvil 130 to move in an axial direction with respect to driveshaft 150.
According to one or more embodiments, hammer 120 includes an inertial body. The lower surface of the inertial body of hammer 120 is generally planar with the exception of one or more downward protruding punches 126 that engage the upper surface of anvil 130. The upper control surface 131 of anvil 130 includes one or more elevated cams 133 (e.g.,
Referring to
Referring now to
Although
As described hereinabove, percussive hammer assembly 100 may be used for multiple purposes, including as formation drilling, well cleaning, cement plug drilling, etc. Percussive hammer assembly 100 may be run on drill string 32 (
Percussive hammer assembly 100 is easily configurable and may be adjusted before each use to match requirements. For example, based on one or more wellbore or formation parameters, it may be determined that a particular impact frequency and force should be used. The number of hammer punches 126 and cams 133 on control surface 131 may be adjusted to provide a varied number of impacts per rotation, as desired. By adjusting the angle and height of cams 133 and the stiffness of biasing springs 122, 132, it is possible to adjust impact force to suit demands. Moreover, percussive hammer assembly 100 may have modular configuration for use with numerous types of rotary motors, including electric, hydraulic, hydraulic-electric, and mud motors, and within multiple types of conveyance systems, including a conventional drill strings, wireline cable, and coiled tubing.
In summary, a percussive hammer assembly and a percussive drilling system have been described. Embodiments of the percussive hammer assembly may generally have: A driveshaft rotatable within a housing; a hammer rotatively coupled to and axially slideable about the driveshaft; a drill body rotatively coupled to and axially slideable about a lower end of the driveshaft; an anvil rotatively fixed within the housing, the anvil rotatively capturing an upper end of the drill body, the anvil defining a control surface in contact with the hammer; and a first cam formed on the control surface; whereby rotation of the driveshaft with respect to the housing is operable to rotate the hammer along the control surface, and the first cam is operable to axially move the hammer with respect to the driveshaft. Embodiments of the percussive drilling system may generally have: A driveshaft rotatable within a housing; a motor operable to rotate the driveshaft with respect to the housing; a hammer rotatively coupled to and axially slideable about the driveshaft; a drill body rotatively coupled to and axially slideable about a lower end of the driveshaft; a bit connected to a lower end of the drill body; an anvil rotatively fixed within the housing, the anvil rotatively capturing an upper end of the drill body, the anvil defining a control surface in contact with the hammer; and a first cam formed on the control surface; whereby rotation of the driveshaft with respect to the housing is operable to rotate the hammer along the control surface, and the first cam is operable to axially move the hammer with respect to the driveshaft.
Any of the foregoing embodiments may include any one of the following elements or characteristics, alone or in combination with each other: A hammer spring disposed within the housing biasing the hammer towards the anvil; the first cam defines first surface having a continuous inclination and a second surface that is substantially parallel with the driveshaft; as the hammer rotates along the first surface, the hammer spring is compressed; when the hammer rotates past the second service, the hammer spring forces the hammer to rapidly strike the anvil; the anvil is axially slideable within the housing; the percussive hammer assembly further comprises an anvil spring disposed within the housing biasing the anvil towards the hammer includes an inertial body; the hammer includes an axial bore formed through the inertial body coupled to the driveshaft with a spline fitting; a first elongate punch protruding from the inertial body engaging the control surface of the anvil; a second elongate punch protruding from the inertial body engaging the control surface of the anvil; the drill body includes an axial bore formed therein coupled to the driveshaft with a spline fitting; the axial bore is formed through the drill body; a lower end of the axial bore forms a connector dimensioned to receive a bit; the driveshaft is tubular and defines a hollow interior in fluid communication with the lower end of the axial bore; a second cam formed on the control surface of the anvil; a conveyance coupled to and suspending the housing; the conveyance is a wireline cable; the motor is an electric motor; the conveyance is a coiled tubing; a drill string coupled to and suspending the housing; the motor is a mud motor; and the housing encloses the motor.
While various embodiments have been illustrated in detail, the disclosure is not limited to the embodiments shown. Modifications and adaptations of the above embodiments may occur to those skilled in the art. Such modifications and adaptations are in the spirit and scope of the disclosure.
Filing Document | Filing Date | Country | Kind |
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PCT/US2015/039537 | 7/8/2015 | WO | 00 |
Publishing Document | Publishing Date | Country | Kind |
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WO2017/007469 | 1/12/2017 | WO | A |
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Number | Date | Country | |
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20180163474 A1 | Jun 2018 | US |