WO2025181402A1 - Appareil de fond de trou destiné à être utilisé dans un trou de forage - Google Patents

Appareil de fond de trou destiné à être utilisé dans un trou de forage

Info

Publication number
WO2025181402A1
WO2025181402A1 PCT/EP2025/055722 EP2025055722W WO2025181402A1 WO 2025181402 A1 WO2025181402 A1 WO 2025181402A1 EP 2025055722 W EP2025055722 W EP 2025055722W WO 2025181402 A1 WO2025181402 A1 WO 2025181402A1
Authority
WO
WIPO (PCT)
Prior art keywords
anchor
borehole
downhole
distal tool
control
Prior art date
Legal status (The legal status is an assumption and is not a legal conclusion. Google has not performed a legal analysis and makes no representation as to the accuracy of the status listed.)
Pending
Application number
PCT/EP2025/055722
Other languages
English (en)
Inventor
Liam Anthony LINES
William David Murray
Anthony Richard Glover
Current Assignee (The listed assignees may be inaccurate. Google has not performed a legal analysis and makes no representation or warranty as to the accuracy of the list.)
GA Drilling AS
Original Assignee
GA Drilling AS
Priority date (The priority date is an assumption and is not a legal conclusion. Google has not performed a legal analysis and makes no representation as to the accuracy of the date listed.)
Filing date
Publication date
Priority claimed from GB2405172.4A external-priority patent/GB2638791A/en
Priority claimed from PCT/EP2024/080340 external-priority patent/WO2025088194A1/fr
Application filed by GA Drilling AS filed Critical GA Drilling AS
Priority to PCT/EP2025/073604 priority Critical patent/WO2026037967A1/fr
Publication of WO2025181402A1 publication Critical patent/WO2025181402A1/fr
Pending legal-status Critical Current
Anticipated expiration legal-status Critical

Links

Classifications

    • EFIXED CONSTRUCTIONS
    • E21EARTH OR ROCK DRILLING; MINING
    • E21BEARTH OR ROCK DRILLING; OBTAINING OIL, GAS, WATER, SOLUBLE OR MELTABLE MATERIALS OR A SLURRY OF MINERALS FROM WELLS
    • E21B4/00Drives for drilling, used in the borehole
    • E21B4/18Anchoring or feeding in the borehole
    • EFIXED CONSTRUCTIONS
    • E21EARTH OR ROCK DRILLING; MINING
    • E21BEARTH OR ROCK DRILLING; OBTAINING OIL, GAS, WATER, SOLUBLE OR MELTABLE MATERIALS OR A SLURRY OF MINERALS FROM WELLS
    • E21B23/00Apparatus for displacing, setting, locking, releasing or removing tools, packers or the like in boreholes or wells
    • E21B23/001Self-propelling systems or apparatus, e.g. for moving tools within the horizontal portion of a borehole
    • EFIXED CONSTRUCTIONS
    • E21EARTH OR ROCK DRILLING; MINING
    • E21BEARTH OR ROCK DRILLING; OBTAINING OIL, GAS, WATER, SOLUBLE OR MELTABLE MATERIALS OR A SLURRY OF MINERALS FROM WELLS
    • E21B23/00Apparatus for displacing, setting, locking, releasing or removing tools, packers or the like in boreholes or wells
    • E21B23/01Apparatus for displacing, setting, locking, releasing or removing tools, packers or the like in boreholes or wells for anchoring the tools or the like
    • EFIXED CONSTRUCTIONS
    • E21EARTH OR ROCK DRILLING; MINING
    • E21BEARTH OR ROCK DRILLING; OBTAINING OIL, GAS, WATER, SOLUBLE OR MELTABLE MATERIALS OR A SLURRY OF MINERALS FROM WELLS
    • E21B44/00Automatic control systems specially adapted for drilling operations, i.e. self-operating systems which function to carry out or modify a drilling operation without intervention of a human operator, e.g. computer-controlled drilling systems; Systems specially adapted for monitoring a plurality of drilling variables or conditions

Definitions

  • This invention relates to downhole apparatus for use in a drillstring in a borehole. For example, in a subterranean drilling, milling or completions operation.
  • a borehole is drilled through a formation in the earth.
  • a drillstring extends from an upbore location, typically on the surface, to the foot of the borehole and typically comprises components known as the bottom hole assembly which may terminate in a drill bit.
  • a drill bit is located at the distal end of the drillstring. The drill bit can be rotated by a downhole motor, allowing the bit to advance through the formation to form the borehole.
  • a common occurrence during drilling is that changes in the reactive torque at the drill bit or friction between the drillstring and borehole can initiate torsional oscillations, including stickslip.
  • Stick-slip occurs when the lower section of the drillstring stops rotating while the drillstring above continues to rotate. This can cause the drillstring to wind up, after which the stuck element slips and rotates again.
  • the drillstring can act like a long torsional spring and is able to store significant amounts of torsional energy. Torsional oscillations in the drillstring can cause damage to the drillstring, bottom hole assembly and the borehole, and result in poor drilling performance.
  • Deep geothermal wells can in some cases be seen as prohibitively expensive and technically challenging due to the high temperatures, hard rock and extreme depths. Deep geothermal wells are also likely to be some of the most complex wells drilled due to geologic complexity (such as faults, fractures and high friction), directional complexity (for example, intersections, geosteering, long laterals and low well spacing) and well control (for example, losses and high pressure zones).
  • geologic complexity such as faults, fractures and high friction
  • directional complexity for example, intersections, geosteering, long laterals and low well spacing
  • well control for example, losses and high pressure zones.
  • a drillstring anchor can be used to axially stabilize the drillstring and to reduce torsional vibrations, which can help to mitigate these issues and reduce the likelihood of significant and potentially damaging oscillations along the drillstring.
  • the control arrangement may be a control unit.
  • the control arrangement may be or comprise a processor.
  • the control arrangement may alternatively be implemented by an analogue electrical circuit or mechanical and/or hydraulic arrangement.
  • the control arrangement for example the processor, may be programmed to execute a control strategy for controlling the apparatus to apply longitudinal force to the distal tool.
  • the downhole apparatus may comprise the control arrangement.
  • the anchor may comprise the control arrangement.
  • the control arrangement may be local to the anchor.
  • the control arrangement may be integral with the anchor.
  • the control arrangement may be remote from the downhole apparatus.
  • the control arrangement may be located at the surface of the wellbore.
  • the control arrangement may be arranged for automatically controlling the apparatus to apply longitudinal force to the distal tool in the ways described herein.
  • the anchor may have a gripping element configured to engage the borehole.
  • the gripping element may react axial force (which may also be referred to as longitudinal force) between the anchor and the borehole.
  • the gripping element may react rotational (for example, torsional) force between the anchor and the borehole.
  • the gripping element may react axial and rotational forces between the anchor and the borehole.
  • the gripping element may restrict relative axial movement between the anchor and the borehole.
  • the gripping element may restrict relative rotational movement between the anchor and the borehole.
  • the gripping element may restrict relative axial and rotational movement between the anchor and the borehole.
  • the restriction of axial movement may be between the gripping element of the anchor and the borehole.
  • a downhole apparatus for use in a drillstring in a borehole, the drillstring terminating in a distal tool
  • the downhole apparatus comprising an anchor having a gripping element for engaging the borehole to react axial and/or rotational force between the anchor and the borehole, the anchor being communicatively connectable with a control arrangement arranged for, in dependence on inputs received from one or more sensors for sensing the state of the downhole apparatus and/or the distal tool, controlling the apparatus to apply longitudinal force to the distal tool.
  • the control arrangement or control strategy may control the apparatus to adjust or vary an amount of engagement between the distal tool and the borehole (for example, the bottom of the borehole).
  • the control arrangement or control strategy may control the apparatus to adjust the surface area of the distal tool that is in contact with the bottom of the borehole or the depth of cut of the distal tool.
  • the control arrangement or control strategy may control the apparatus to maintain engagement between the distal tool and the borehole (for example, the bottom or distal end of the borehole).
  • the sensors may be downhole sensors or may be sensors at the surface of the borehole.
  • the control arrangement or control strategy may control the apparatus to optimize and/or maximize engagement between the distal tool and the bottom of the borehole.
  • the control arrangement or control strategy may control the apparatus to maximize the surface area of the distal tool that is in contact with the bottom of the borehole.
  • the control arrangement may be configured to: determine one or more downhole parameter measurements from the inputs received from the one or more downhole sensors; and control the anchor to apply longitudinal force to the distal tool in dependence on the one or more downhole parameter measurements.
  • the control arrangement may be configured to: determine one or more parameter measurements measured at the surface of the wellbore; and control the anchor to apply longitudinal force to the distal tool in dependence on the one or more parameter measurements.
  • the one or more downhole parameter measurements may comprise one or more of pressure, displacement (or a rate of change therefore, for example rate of penetration of a drill bit), downhole weight on the distal tool and downhole torque on the distal tool.
  • the processor may determine from a measurement of pressure at the distal tool whether the distal tool is engaged with the borehole (for example, the bottom of the borehole for a straight wellbore) and may adjust the longitudinal force applied to the distal tool to allow the distal tool to remain in constant engagement with the wellbore.
  • the drillstring may comprise a rotational drive proximal of the distal tool for driving the distal tool to rotate.
  • the rotational drive may be distal of the anchor.
  • the control arrangement may be arranged for controlling the longitudinal force applied to the distal tool to maintain the rotational drive within one or more predetermined operational ranges.
  • the one or more predetermined operational ranges may be predetermined ranges of one or more of rotational speed, torque and power of the rotational drive.
  • the distal tool may be driven to rotate from the surface via the drillstring.
  • the rotational drive may comprise a downhole motor or turbine.
  • a motor may generate rotation from electrical energy.
  • a turbine may generate rotation from longitudinal flow of fluid in the wellbore.
  • the rotational drive may comprise a mud motor.
  • the one or more downhole parameter measurements may comprise a differential pressure between drilling fluid passing through the motor and drilling fluid in the annulus of the borehole.
  • the control arrangement may be configured to, in dependence on inputs received from the one or more sensors, control the apparatus to apply longitudinal force to the distal tool by means of the anchor.
  • the one or more sensors may be local to the downhole apparatus. At least one of the one or more downhole sensors may be local to the anchor.
  • the anchor may comprise one or more of the downhole sensors. Alternatively, one or more of the sensors may be part of other tools in the BHA (such as an MWD tool). The anchor may communicate with other tools in the BHA.
  • the anchor may comprise an internal channel for conveying the flow of drilling fluid to the distal tool.
  • the control arrangement may be configured to maintain a differential pressure between the channel and the annulus of the borehole at a predetermined value or within a predetermined range.
  • the differential pressure may be maintained to allow a predetermined longitudinal force or range of longitudinal force (for example, a predetermined weight on bit (WOB) or range of weight on bit) to be applied to the distal tool.
  • a predetermined longitudinal force or range of longitudinal force for example, a predetermined weight on bit (WOB) or range of weight on bit
  • WOB weight on bit
  • the control arrangement may, or the control strategy may be executed to, adjust the longitudinal force applied to the distal tool to maintain the differential pressure within a predetermined range.
  • the longitudinal force may provide weight on the distal tool.
  • the longitudinal force may provide weight on bit to the bit.
  • the control arrangement may be configured to, or the processor may be configured to execute the control strategy to, apply longitudinal force to the distal tool to control a depth- of-cut or a rate of penetration of the distal tool.
  • a downhole apparatus for use in a drillstring in a borehole, the drillstring terminating in a distal tool, the downhole apparatus comprising an anchor having a gripping element for engaging the borehole to react axial and/or rotational force between the anchor and the borehole, the anchor being communicatively connectable with a control arrangement arranged to control the apparatus to, in response to the detection of a condition associated with a reduction in drilling efficiency and/or a condition associated with damage to the drillstring, adjust longitudinal force applied by means of the anchor to the distal tool.
  • the control arrangement may be configured to, in response to the detection of a condition associated with a reduction in drilling efficiency and/or a condition associated with damage to the drillstring and/or the borehole, increase or reduce the longitudinal force applied by means of the anchor to the distal tool.
  • the drillstring may comprise a rotational drive proximal of the distal tool for applying rotational drive to the distal tool.
  • the control arrangement may be configured to, in response to the detection of a condition associated with a reduction in drilling efficiency and/or a condition associated with damage to the drillstring and/or the wellbore, adjust the longitudinal force applied by means of the anchor to the distal tool to stabilize or optimize requirements (such as torque requirements) of the rotational drive and/or stabilize rotational output from the rotational drive.
  • the control arrangement may be configured to, in response to the detection of a condition associated with a reduction in drilling efficiency and/or a condition associated with damage to the drillstring and/or the wellbore, increase the longitudinal force applied by means of the anchor to the distal tool to maintain engagement between the distal tool and the borehole.
  • the control arrangement may be configured to maintain the rotational drive within one or more predetermined operational ranges.
  • the one or more predetermined operational ranges may be predetermined ranges of one or more of rotational speed, torque and power of the rotational drive.
  • the control arrangement may be configured to detect a condition associated with a reduction in drilling efficiency in dependence on inputs from one or more downhole sensors local to the downhole apparatus.
  • the one or more downhole sensors may comprise one or more sensors configured to measure or infer pressure, downhole weight on the distal tool and downhole torque on the distal tool.
  • the anchor may be configured to apply longitudinal force to the distal tool via the drillstring (e.g. via one or more components of the drillstring distal of the anchor and/or proximal of the distal tool).
  • the anchor may comprise an internal channel for conveying the flow of drilling fluid to the distal tool, wherein the control arrangement is configured to maintain a differential pressure between the channel and the annulus of the borehole at a predetermined value or within a predetermined range.
  • the differential pressure may be maintained to allow a predetermined longitudinal force or range of longitudinal force (for example, a predetermined weight on bit or range of weight on bit) to be applied to the distal tool.
  • the gripping element may be for engaging the borehole to react axial and/or rotational force between the gripping element and the borehole.
  • the gripping element may be for engaging the borehole to restrict relative axial and/or rotational movement between the gripping element and the borehole.
  • the flow of drilling fluid through the anchor may be used to provide the longitudinal force applied to the distal tool.
  • the pressure difference between the drilling fluid being pumped down the inside the anchor and the drilling fluid returning to surface in the annular space around the outside of anchor can be used to perform work. This pressure difference can typically be many 100s of psi.
  • the higher-pressure drilling fluid from the inside of the tool can be directed (via valves or other means) to one side of an axial piston and the lower pressure annular drilling fluid can be directed (via valves or other means) to the other side of an axial piston.
  • a method of retracting a downhole tool from a wellbore comprising: performing a downhole operation using a drillstring comprising a downhole tool and an anchor having a gripping element for engaging the borehole to react axial and/or rotational force between the anchor and the borehole; operating the anchor to move through the wellbore in a surface-bound direction so as to retract the downhole tool from the wellbore.
  • a downhole apparatus for use in a drillstring in a borehole, the drillstring terminating in a distal tool
  • the downhole apparatus comprising an anchor having a gripping element for engaging the borehole to react axial and/or rotational force between the anchor and the borehole, the anchor being communicatively connectable with a control arrangement arranged to, in dependence on inputs received from one or more sensors for sensing the state of the downhole apparatus and/or the distal tool, control the apparatus to apply longitudinal force to the distal tool to achieve a predetermined rate of penetration of the distal tool.
  • the sensors may be downhole sensors or may be sensors at the surface of the borehole.
  • the anchor may comprise a linear position sensor for determining a relative displacement between the gripping element and one or more components axially fast with the distal tool, wherein the control arrangement is configured to determine whether the predetermined rate of penetration of the distal tool has been achieved in dependence on measurements acquired by the linear position sensor.
  • the distal tool may be a drill bit.
  • the downhole apparatus may comprise a weight on bit sensor and/or a torque on bit sensor.
  • the control arrangement may be configured to control the apparatus to apply longitudinal force to the distal tool to achieve a predetermined weight on bit and/or torque on bit, which may be determined in dependence on measurements by the sensor(s).
  • the drillstring or the distal tool may comprise a rotational speed sensor, wherein the control arrangement is configured to control the apparatus to apply longitudinal force to the distal tool to achieve a predetermined rotational speed of the drillstring or distal tool as measured by the sensor.
  • the control arrangement may comprise a processor and may be configured to execute an efficiency algorithm to control the anchor to apply longitudinal force to the distal tool in dependence on measurements acquired by one or more sensors.
  • the distal tool may be, for example, a conventional drill bit, a plasma drilling head or other drilling mechanism.
  • a rotational drive may not be used.
  • the distal tool is a plasma drilling head
  • rotation of the head may not be needed to progress the borehole.
  • the control arrangement may be configured to determine the rotational speed of the rotational drive.
  • the control arrangement may be configured to receive data from one or more downhole sensors.
  • the one or more downhole sensors may comprise a vibration sensor configured to detect vibration transverse to the longitudinal axis of the drillstring.
  • the control arrangement may be configured to determine the rotational speed of the rotation drive in dependence on input received from the vibration sensor and a known configuration of the rotational drive.
  • the known configuration of the rotational drive may be a number of rotor lobes of the rotational drive.
  • the vibration sensor may comprise a lateral accelerometer.
  • the downhole apparatus may comprise the control arrangement.
  • the anchor may comprise the control arrangement.
  • the apparatus may be communicatively connectable with a downhole control arrangement (for example, a control unit).
  • the control arrangement may be at the surface and may be connected to the downhole apparatus using a wired connection, such as electrified wireline.
  • the control unit may comprise the processor.
  • the control arrangement may be configured to adjust the configuration of the anchor and/or one or more other elements coupled to the anchor (for example, coupled directly or indirectly at the distal end of the anchor) in response to one or more signals.
  • the one or more other elements may be communicatively connectable to the anchor. This may allow signals to be passed through the anchor and/or for signals to be transferred between the anchor and components of a bottom hole assembly than the anchor.
  • the apparatus may comprise the control arrangement.
  • the control arrangement may comprise the processor and one or more memories.
  • the memory may store in a non-transient way code that is executable by the processor to implement the methods described herein.
  • Adjusting the configuration of the anchor may comprise adjusting the configuration of the gripper and/or adjusting the configuration of one or more other parts of the anchor, such as one or more axial pistons for applying an axial force to the drillstring or one or more of the other elements coupled with the anchor, such as a drill bit.
  • the apparatus may further comprise or be communicatively connectable with one or more measurement devices for determining one or more downhole parameters. For example, torque, axial force (such as weight on bit), bending force, pressure and temperature.
  • the gripping element may be configured to grip the borehole to restrict relative axial movement between the anchor (for example, the gripping element of the anchor) and the borehole.
  • the gripping element may be configured to grip the borehole to restrict relative rotation between the anchor (for example, the gripping element of the anchor) and the borehole.
  • the anchor may be configured to react axial loads to the borehole when the gripping element is gripping the borehole.
  • the anchor may be configured to react torsional loads to the borehole when the gripping element is gripping the borehole.
  • the gripping element may be configured to grip the borehole to restrict both relative rotation and relative axial movement between the anchor and the borehole.
  • the anchor may be configured to react both axial loads and torsional loads to the borehole when the gripping element is gripping the borehole.
  • the anchor may be configured to apply longitudinal force to one or more distal downhole components coupled to the anchor.
  • the anchor may be part of a bottom hole assembly, wherein the anchor is configured to urge the bottom hole assembly into the borehole.
  • the anchor may be coupled with a tool for performing a downhole operation at the distal end of the bottom hole assembly.
  • the anchor may be configured to apply weight to the tool to urge the tool into the borehole or against the bottom of the borehole.
  • the anchor may be configured to apply weight to the tool to urge the tool against the distal end of the borehole.
  • the anchor may comprise multiple gripping elements each configured to move axially relative to a body of the anchor.
  • the multiple gripping elements may be disposed on the same body, or across multiple body parts that are axially separated along the longitudinal axis of the apparatus.
  • the multiple body parts may each act as separate anchors that are independently controlled.
  • the anchor may comprise a drive mechanism for advancing one gripping element downhole and/or uphole relative to at least one other gripping element.
  • each body part having multiple gripping elements each configured to move axially relatively to its respective body part
  • each body part may have a respective drive mechanism for advancing one gripping element downhole and/or uphole relative to at least one other gripping element.
  • the or each gripping element may have an associated actuator.
  • the actuator may be capable of being driven to cause the respective gripping element to adopt at least one of (a) a first state in which it is urged outwardly for gripping the borehole and (b) a second, passive state.
  • one actuator may be used to drive multiple grippers, or each gripper may have its own actuator.
  • the operation of the or each gripping element may be powered by one or more of the following: the flow of drilling fluid through the anchor; an energy store (such as a battery or other energy source or a reservoir of hydraulic fluid), a thermal gradient between the interior of the anchor and the annulus of the borehole; via an electric conduit connectable with the connector (where electrical power is supplied from the surface); by differential rotation between the anchor and the drillstring or the output of a mud motor.
  • an energy store such as a battery or other energy source or a reservoir of hydraulic fluid
  • a thermal gradient between the interior of the anchor and the annulus of the borehole via an electric conduit connectable with the connector (where electrical power is supplied from the surface); by differential rotation between the anchor and the drillstring or the output of a mud motor.
  • the apparatus may be part of a downhole assembly comprising one or more additional downhole tools.
  • the one or more additional downhole tools may comprise one or more of the following: a measurement-while-drilling tool, a logging-while-drilling tool, a fluid conditioning module to regulate hydraulic fluid and/or filter drilling fluid, an orienter tool, a fixed or variable bent sub, a rotary steerable system, a downhole motor (such as a steerable mud motor) for providing rotational drive and/or torque to a drilling or milling tool at a distal end of the drillstring.
  • the drillstring may comprise one or more drilling tools.
  • the drilling tool at the distal end of the drillstring may comprise a conventional rock bit, a PDC bit, a hybrid bit or a plasma bit.
  • the apparatus may comprise one or more channels for receiving drilling fluid from the drillstring and conveying the drilling fluid towards the distal end of the drillstring.
  • the anchor may restrict relative axial movement between the anchor and the drillstring.
  • control arrangement may be configured to implement a control strategy.
  • the control strategy implemented by the control arrangement may be a closed-loop control strategy.
  • the closed-loop control strategy may be such as to generate control signals in dependence on a comparison between a desired state of the equipment and a sensed state of the equipment.
  • the control strategy may be an adaptive control strategy.
  • the borehole may be a wellbore.
  • the wellbore may be formed to aid the exploration and/or recovery of natural resources such as oil, gas or water.
  • the borehole may be another type of borehole.
  • the borehole may comprise one or more non-vertical sections.
  • FIG. 1 schematically illustrates an example of a drilling system, illustrated at a subterranean location in a borehole during a downhole operation;
  • FIG. 2 schematically illustrates an example of an anchor comprising multiple gripping segments
  • FIG.s 3(a)-3(c) schematically illustrate an example of a gripper made from a hard material
  • FIG.s 4a and 4b schematically illustrate an example of the application of a longitudinal force by the anchor to a distal tool
  • FIG. 5 schematically illustrates a coupling between the anchor and a portion of the drillstring above the anchor
  • FIG. 6 schematically illustrates an example of a control unit
  • FIG. 7 shows the steps of an exemplary method for retracting a downhole tool from a borehole.
  • FIG. 1 schematically illustrates an example of a drilling system illustrated at a subterranean location in a borehole (not to scale). Although in FIG. 1 for illustrative purposes the borehole is shown as vertical, in practice the borehole may have a more complicated two- or three- dimensional path and may include multiple branches.
  • a rig 101 provides support and/or power to a drillstring.
  • the drillstring may comprise, for example, conventional drill pipe or coiled tubing.
  • the drillstring comprises multiple components and terminates in a distal tool 108.
  • the borehole is shown at 104.
  • the borehole may be at least partially lined with casing 105 and cement 106.
  • the portion of the drillstring shown at 102 may provide torque and/or power (for example, rotary, thermal, and/or electrical power) to the bottom hole assembly (BHA), shown generally at 107.
  • the BHA is part of the drillstring and may comprise a tool or other component 108.
  • the tool 108 may be a drilling tool.
  • the tool 108 may be, for example, a drill bit.
  • tool 108 in FIG. 1 may be a conventional drill bit such as a polycrystalline diamond compact (PDC) drill bit, a roller cone drill bit or a hybrid bit (a combination of PDC and roller cone).
  • Drilling fluid can be pumped to the component through the drillstring and released into the annulus of the borehole, as shown at 109.
  • the drilling fluid 109 acts to convey cuttings to the surface.
  • the drilling fluid may be referred to as drilling mud.
  • the implementation shown in figure 1 employs rotary drilling.
  • the drilling tool or bit 108 can be driven to rotate by a rotary drive unit 110 to form the borehole in the formation.
  • the rotary drive unit may be a mud motor.
  • the motor may be a positive-displacement mud (PDM) motor.
  • the drill bit may be driven by other downhole rotary drive devices such as electric motors, pneumatic motors or a drilling turbine.
  • a motor for rotating the bit may not be required.
  • the rotary drive unit may be bent, for instance a bent motor, which may allow for improved directional control when performing directional drilling. It is also possible for the downhole rotary drive unit to be omitted and for the drillstring to be rotated from the surface.
  • downhole is used to refer to a component which in operation is located in a borehole.
  • a downhole component may be located proximally to a drilling site at the distal end of the borehole.
  • components located at the surface of the borehole may be part of a surface system of the drilling system.
  • the BHA 107 can also comprise one or more additional components.
  • the components described below are exemplary and the BHA may alternatively or additionally comprise other components.
  • the described components need not be immediately adjacent to one another and may be separated by further components.
  • the component shown at 111 is a measurement-while-drilling (MWD) tool.
  • the MWD tool can sense data relating to the direction of the borehole and/or the position of the drill head and/or the rock formation that is being drilled. That sensed data can be processed downhole, e.g. for closed loop control and optimization of the drilling process, and/or transmitted to the surface for processing at the surface.
  • Data collected by the MWD tool may include any one or more of shock, vibration, pressure, weight and torque data.
  • the MWD tool may comprise magnetometers for measuring the earth’s magnetic and gravitational fields and/or accelerometers for measuring accelerations of the MWD tool, and from which are derived the position of the instrument in the subsurface and hence the trajectory of the borehole. Additionally, there may be other measurement instruments, such as strain-gauges, accelerometers, pressure sensors and gyroscopes to measure the mechanical stresses imposed on, and the motion of, the MWD tool.
  • the MWD tool 111 may comprise a means of transmitting information to the surface.
  • the MWD tool may utilize conventional telemetry techniques such as mud pulse telemetry.
  • the operation of a valve in the fluid flow-path in the drillstring, or between the interior of the drillstring and the annulus, may induce pressure variations which may be detected using pressure and/or flow measurements at the surface.
  • the MWD tool may be integrated with the cable(s) in the coiled tubing for higher density data and more reliable decoding in deep applications with challenging mud properties.
  • the MWD tool may transmit data to the surface using electromagnetic signals, for instance varying a voltage across an insulated section of drillstring is varied, or by employing electrical signals through wired pipe (if present).
  • the telemetry system may allow for bidirectional communication, allowing the MWD tool to receive signals transmitted from the surface.
  • a logging while drilling (LWD) tool may alternatively or additionally be used.
  • the LWD tool can store data downhole.
  • the component shown at 112 is a steering device.
  • the steering device may be an orienter tool.
  • the orienter may be a high torque orienter.
  • the orienter can electrically or hydraulically orient the motor to direct the borehole. This can help to minimize tortuosity by allowing a steerable motor to be rotated to drill straight ahead.
  • the steering device may be communicatively coupled to the surface. This can also allow for closed loop trajectory control due to high-speed well directional data and control of the orienter via a communication link such as an E-line. This may allow the steering device to receive commands transmitted from the surface, for example via the E-line, which may allow the drill bit to be urged to follow a desired trajectory.
  • the RSS may act as the steering device 112 and a separate orienter might be omitted.
  • the RSS may be used to steer the motor to direct the borehole.
  • the steering device 112 can control the direction of the drill bit using one or more of (i) applying force against the borehole to induce a reaction that turns the drill path, or (ii) inducing curvature directly in the drillstring.
  • the component shown at 113 is an anchor, which will be described in more detail below.
  • the anchor 113 may be connected to the part of the drillstring 102 via a coupling 114, such as a swivel.
  • the coupling 114 may couple the anchor 113 to a connector 115.
  • the connector 115 allows the portion of the drillstring 102 above the anchor to be connected to the proximal (i.e. upbore) end of the coupling 114.
  • the anchor 113 can transfer axial forces and/or reactive torque from the BHA to the borehole, as will be described in more detail below. This may help to prevent the initiation of torsional oscillations in the drillstring, including stick-slip.
  • the anchor is designed to remove at least some, and preferably all, of the torque from the drillstring when reactive torque is transferred to the borehole.
  • anchor 113 may be configured to be mounted above the rotary drive. The anchor may grip the walls of the borehole and may help to react torque from the motor and/or stabilize the operation of the motor.
  • the coupling 114 may be a flexible coupling.
  • a flexible coupling may allow relative movement of the connector for connection to the drillstring and the anchor about and/or along one or more axes.
  • the coupling may be rotatable and/or axially compliant, as will be described in more detail later.
  • the system described above with reference to FIG. 1 is for performing a rotary drilling operation.
  • the system uses a downhole motor to provide rotational drive to a drill bit below the anchor.
  • the anchor described herein may alternatively be utilized in non-rotary drilling applications.
  • Non-limiting examples of non-rotary drilling applications include jetting, plasma drilling (a contactless drilling technique that uses high-voltage pulses to fracture the rock) and other compatible operations in a borehole, such as a milling, completion or plug and abandonment operations.
  • the drilling fluid may be supplied to the tool (and more distal components such as the drill bit) from a tank 120 at the surface of the borehole.
  • the drilling fluid may be fed to the BHA via pipes 121.
  • the tank may be coupled to a chiller 125.
  • the chiller may cool the drilling fluid.
  • the chiller may keep the drilling fluid at a temperature that is below a predetermined threshold. This may allow for a reduction in bottom hole temperature, making it possible to drill in hotter environments, such as at deeper depths.
  • the fluid may return to the mud tanks via a further flow channel and shale shakers (not shown).
  • One or more surface computational platforms 123 may perform functions such as controlling the operation of the auto-driller, top-drive and mud-pumps, or those components may contain their own embedded controllers.
  • the surface computational platform 123 can communicate with offsite computers or individuals, using an antenna or cable 124, which may enable effective control to be conducted remotely from the well site.
  • the drilling rig may be instrumented, so that parameters related to the drilling operation may be determined at the surface. For example, one or more of the tension applied by the portion of the drillstring 102 to the drilling line (hook-load), the vertical motion of the top of the string (the surface rate-of-penetration), the torque applied to and the rotation speed of the string, and the flow rate and pressure of the drilling fluid at surface.
  • tension applied by the portion of the drillstring 102 to the drilling line hook-load
  • the vertical motion of the top of the string the surface rate-of-penetration
  • torque applied to and the rotation speed of the string the flow rate and pressure of the drilling fluid at surface.
  • the exemplary BHA shown in FIG. 1 comprises a source of electrical power, which may for example be a fluid-driven turbine, the rotation of which generates an electrical current.
  • the turbine may be driven by drilling fluid flowing through the BHA.
  • Alternative sources of electrical power include batteries or capacitors, or a cable such as an E-line that allows power to be transmitted from the surface.
  • the turbine As the turbine’s rotation speed depends on the flow rate of drilling fluid through the BHA, by measuring the turbine’s rotation speed, the turbine may be used to sense the flow rate of drilling fluid. It may detect changes in flow rate made at the surface by the mud-pump controller and mud-pump through. The flow rate may be modulated so as to transmit information from the surface to the BHA.
  • the BHA may also comprise a fluid conditioning module to regulate hydraulic pressure and/or to filter the drilling fluid.
  • the BHA may comprise additional components such as drill collars, stabilizers, reamers, hole-openers and bit subs.
  • the anchor comprises one or more gripping elements (referred to herein as grippers).
  • the anchor may comprise a channel for receiving a shaft.
  • the anchor may comprise the shaft.
  • the shaft may pass through the channel in the interior of the anchor.
  • the shaft can move longitudinally within the anchor.
  • the shaft can rotate relative to the channel.
  • the shaft may move independently of the gripper(s).
  • the shaft may be axially fast with components of the drillstring or BHA below the anchor. That is, the shaft may move with the components of the drillstring below the anchor.
  • gripper(s) of the anchor is/are gripping the wellbore, the shaft may be configured to move relative to the gripper(s).
  • the shaft when the gripper(s) is/are gripping the wellbore, the shaft may be rotatable relative to the channel of the anchor through which the shaft passes. This can allow the BHA/bit to be rotated while the grippers are axially and rotatable locked to the borehole.
  • Torsional anchoring may be achieved using keys or protrusions on the exterior of the shaft and keyways in a surface of the anchor facing the shaft (e.g. in the channel) that engage the keys and prevent relative rotation between the shaft and the wellbore when the one or more grippers of the anchor are activated to grip the wellbore.
  • the gripper(s) may grip the wellbore fully or partially. When the gripper(s) grip the wellbore, relative axial and/or rotational movement between the gripper(s) and the borehole may be partially or fully restricted.
  • FIG. 2 shows an example of an anchor 113.
  • the anchor 113 comprises multiple gripping segments 201 , 202 each comprising one or more grippers 203.
  • each gripping segment 201 , 202 may comprise multiple grippers.
  • the gripping segments 201 , 202 can be moved longitudinally relative to each other using a walking mechanism.
  • the use of multiple electrically coordinated gripping segments may allow for a coordinated downhole operation.
  • the gripping segments may be coordinated via a control arrangement, such as a control unit 600 of the anchor.
  • the control unit 600 may also allow for downlinking in non-wired I conventional drilling applications and communication with other BHA tools.
  • the control unit may optionally use MWD, LWD and/or RSS technology.
  • the anchor 113 comprises a first gripping segment 201 and a second gripping segment 202.
  • the gripping segment 201 comprises an upper set of grippers 203 and the gripping segment 202 comprises a lower set of grippers 203 (the terms ‘upper’ and ‘lower’ being relative to the end of the borehole).
  • Each gripping segment 201 , 202 comprises a gripper housing 207, 208.
  • the gripper housings house the grippers 203.
  • the gripper housings 207, 208 can move longitudinally relative to the main body of the tool along sections 209, 210 respectively. This can allow drilling to progress, by the main body of the tool advancing along the wellbore, whilst anchoring is active.
  • the range of longitudinal movement along the sections 209, 210 may be referred to as the ‘tool stroke’ (as indicated in FIG. 2).
  • the gripping segments may be caused to grip the wellbore in turn.
  • the handover from one gripping segment to the other may be determined based on the position of the other gripping segment relative to the housing of the anchor, or after a predetermined time since the gripping segment currently gripping was actuated.
  • the segment currently gripping the borehole may release automatically when the other gripping segment is actuated to grip the borehole, or once the other segment is determined to be gripping the borehole, for example when a target gripping force or pressure of a hydraulic actuator is reached.
  • the gripper of a free i.e.
  • gripping segment may be triggered to grip the borehole when the currently-gripping gripping segment is 20mm from the end of its longitudinal range of travel relative to the housing of the anchor.
  • the currently-gripping gripping segment could then be released after another 10mm of drilling (measured by the relative longitudinal movement of the shaft and the channel in which the shaft moves inside the anchor).
  • An alternative implementation is to release the gripper(s) of the currently-gripping gripping segment a fixed time after the activation of the gripper(s) of the free gripping segment is started.
  • the gripper(s) of the free gripping segment may be actuated to grip the borehole when the currently-gripping gripping segment is at a predetermined distance from the end of its longitudinal range of travel relative to the housing.
  • Connector 204 is an upper connector for connection to drill pipe or an upper part of the BHA.
  • Connector 205 is a lower connector for connection to a downhole mud motor or a lower part of the BHA.
  • the connectors may both comprise adapters to industry standard connectors used to connect the anchor to the adjacent sections of the drillstring.
  • the anchor comprises a wired flex portion 206 between the two gripping segments 201 , 202. This may allow the lower gripping segment 202 to electrically communicate with the control unit 600 and/or the upper gripping segment 201. This can allow control signals and/or power to be supplied to the lower gripping segment from the control unit 600.
  • the anchor may be actively controlled from a power source to push the drillstring, or to push a shaft extending through the anchor and coupled to the drillstring, in a downhole direction and in that way apply weight-on-bit to a drill bit, or apply weight to another downhole tool, at the distal end of the drillstring.
  • the anchor may be configured or operated to apply axial force to the BHA below the anchor to urge the BHA into the borehole (i.e. in the downhole direction). Axial forces may also be applied to the drillstring in a similar way by controlling the anchor to pull the shaft in an uphole direction. This may be useful for retracting a tool.
  • one or more of the gripping segments may comprise a piston axially moveable within a cylinder.
  • the piston may be connected to the gripper housing and the cylinder may be connected to the shaft running through the anchor (or vice versa).
  • the anchor comprises the shaft.
  • the shaft is axially/longitudinally fast with the distal tool (that is: longitudinal movement of the shaft results in longitudinal movement of the distal tool). Longitudinal force may be applied to the distal tool by applying longitudinal force to the shaft of the anchor.
  • the enclosed volume between the piston and the cylinder may be connected to an actuator or valve controlling the flow of pressurized fluid (such as oil or drilling fluid) into the volume to cause axial movement of the gripper in response to movement of the shaft and to provide longitudinal force transfer to the drillstring/BHA.
  • This piston may be single acting with a mechanical return (such as a spring) or double acting to allow axial force to be applied to the drillstring in both the uphole and downhole directions.
  • the pressurization of the fluid may be controlled based on the internal pressure of drilling fluid flowing through the anchor, may be regulated to remain substantially constant, or may be modulated based on other factors. This may allow longitudinal force to be applied to the drillstring at the anchor, which may be used to provide weight-on-bit to a drill bit, or weight on another distal tool, at the distal end of the drillstring.
  • the anchor 113 may comprise a single gripping segment that is activated to grip and release the borehole without the walking mechanism or alternatively may comprise individual gripping and push/pull modules that can be connected (for example electrically, mechanically or hydraulically) such that they work in coordination to allow movement and force to be transferred to the drillstring.
  • the anchor advantageously allows the ability to rotate the drillstring (for example, by rotating the shaft running through the anchor) during axial anchoring and for the drillstring to move axially relative to the anchor during torsional anchoring.
  • the drillstring may be free to rotate axially relative to the anchor when the anchor is gripping the wellbore.
  • the drillstring may be rotationally fast with the anchor when the anchor is gripping the wellbore.
  • the apparatus can comprise one or more channels for receiving fluid from the surface via the drillstring and conveying the fluid towards the distal end of the drillstring.
  • fluid such as drilling fluid/mud
  • the anchor comprises one or more grippers that can be activated by one or more actuators.
  • the actuator can be driven to cause the gripper to adopt one of a first state in which it is urged outwardly for gripping the walls of the borehole and a second, passive state.
  • the gripper can grip the borehole.
  • the gripper is configured to exert an outward force on the borehole relative to the longitudinal axis of the anchor. When the gripper is activated, relative rotation between the gripper of the anchor and the borehole can be resisted and this can allow torque to be reacted to the borehole.
  • the term ‘activated’ is used to mean that a gripper of the anchor (or a gripping segment of the anchor comprising multiple grippers) is in a state where it is urged outwardly relative to the central axis of the drillstring. In this state the gripper can grip the borehole.
  • the term ‘deactivated’ is used to mean that a gripper of the anchor (or a gripping segment of the anchor) is in a state where it is exerting a reduced gripping force relative to the activated state. For example, it may be in a state where it is not gripping the borehole. In this state it may not be urged outwardly relative to the central axis.
  • the gripper In the activated state the gripper may be in a location radially outwardly of its location in the deactivated state.
  • the gripper may be biased to one of the states, e.g. by a spring.
  • An energy store can provide the energy supply to one or more actuators for actuating one or more of the grippers.
  • the energy store may be a source of energy generated locally at the anchor.
  • the energy store may be charged or refilled at the surface before running in hole.
  • the energy store may be replenished (e.g. recharged) during or after a trip to the surface.
  • the energy store may be self-contained in the anchor.
  • the energy store is preferably a source of energy stored locally at the anchor.
  • the energy store is preferably suitable for permitting the anchor to operate over an extended period of time without requiring replenishment from the surface of the borehole whilst the anchor is in hole.
  • the energy store may be a source of electricity such as a battery or fuel cell.
  • the anchor may be powered by an alternative energy source, such as a direct supply of power from the surface (for example, via the electrical conduit), via a mud- driven turbine or other mechanisms utilizing the flow of drilling fluid.
  • the drillstring When the anchor is activated (i.e. when the actuator is driven to cause the gripper to grip the borehole), the drillstring may be translatable along its longitudinal axis with respect to the anchor.
  • the anchor is configured to allow relative axial movement of the anchor and the drillstring. This may also be the case when the anchor is deactivated (i.e. when the actuator is driven or released to cause the gripper to not grip the borehole).
  • the anchor When the anchor is activated, relative rotation between the gripper and the borehole can be resisted or restricted. This may be due to physical engagement between the gripper of the anchor and the interior face of the borehole.
  • Additional grippers, gripping segments or separate anchors may be used to increase torque and axial capacity.
  • the ability to use multiple gripping segments can allow for a less stiff system, which may be advantageous for higher curvature wellbores.
  • the gripper is configured to be actuated to move between a passive (i.e. deactivated) state and an outwardly-urged (i.e. activated) state.
  • the gripper In the passive state, the gripper may be radially retracted relative to the activated state.
  • the gripper In the activated state the gripper is configured to restrict relative rotation between the anchor (e.g. the gripper(s) of the anchor) and the borehole.
  • the anchor In both the activated and deactivated states, the anchor is configured to allow axial movement of the shaft. In the deactivated state, the anchor can rotate relative to the borehole.
  • relative rotation between the grippers and the shaft may be restricted, or relative rotation may be allowed to occur.
  • the shaft can move axially relative to the grippers in the downhole direction (i.e. in the direction of the bottom of the borehole, or the furthest reach of the borehole, in the case of a horizontal well) and/or the opposite direction (in the direction of the surface).
  • the gripper(s) can be in the deactivated state when drilling fluid is pumped through the drillstring. Alternatively, the gripper(s) may be activated using mud pressure.
  • the gripper(s) of the anchor may be in the form of pistons or pads configured to exert an outward radial force on the borehole.
  • a pad or piston may comprise teeth that provide resistance and allow the pad to grip the borehole.
  • Various tooth designs may be used.
  • the gripper(s) may have a non-flat portion.
  • the surface of a gripper may have undulations and/or protuberances.
  • the surface of a gripper may comprise ribs, ridges and/or studs.
  • the gripper(s) of the anchor may comprise at least one pad or piston configured to extend in a circumferential or radial direction to engage the borehole.
  • the at least one pad or piston may be configured to move outwardly from the anchor to engage the borehole when the actuator of the respective gripper is driven to cause the gripper to grip the borehole (i.e. when the anchor is activated).
  • the gripper(s) of the anchor each comprise a piston which is capable of being urged outwardly for gripping the borehole from a passive state to an activated state.
  • the piston can move relative to the gripping segment in a direction perpendicular to the longitudinal axis of the anchor between the passive state and the gripping state in which the piston is urged outwardly to cause a gripper area at the end of the piston to grip the borehole.
  • the gripper(s) can move in a radial direction relative to the longitudinal axis of the anchor.
  • the piston may be accommodated in a piston housing that sits in a recess in the gripper housing of the gripping segment.
  • the piston can move outward relative to the piston housing.
  • the piston can move in the radial direction with respect to the longitudinal axis of the anchor.
  • the piston may have a limit of travel within the piston housing.
  • the movement of the piston may be supported in the piston housing by bearings distributed around the circumference of the piston.
  • There may alternatively or additionally be one or more seals disposed around at least part of the piston.
  • the gripper assembly may comprise a return spring.
  • the piston may be double acting, or the absence of hydraulic power applied to achieve the outwardly-urged state may be sufficient to achieve the passive state.
  • the gripper is a cylindrical piston.
  • the gripper may have other forms.
  • the gripper may be a spherical piston or a blade piston.
  • the end of the piston has an insert which engages the borehole to grip the rock.
  • the end of the piston may engage the borehole directly with no additional insert.
  • the piston has an insert at the end of the piston for gripping the borehole.
  • the tip of the piston may be compositionally undifferentiated from the body of the piston and may not have any particular surface formations or surface roughness.
  • the pistons may be controllable to move out from the gripper housing of the gripping segment in the radial direction by different amounts depending on the rock condition and mechanical properties.
  • the pistons may advantageously dig through the filter cake (the solids in the drilling mud that line the borehole) to reach the wall of the borehole.
  • the pistons may be capable of deforming elastically when they are urged outwardly to contact the borehole. Forces resulting from elastic deformation of the pistons may be used in addition to friction with the rock to generate a greater gripping force on the borehole.
  • the gripper 203 is a cylindrical piston with a circularcross section.
  • the base of the piston has a flange 305 for limiting the travel of the piston within the piston housing, as described above.
  • the opposite end 312 of the piston to the base has a chamfered profile.
  • the end of the piston has an insert 311 which engages the borehole to grip the formation.
  • the piston may be hollow to optionally accommodate a spring and defines a chamber for hydraulic fluid.
  • the gripper comprises a hardened insert (made from, for example, Tungsten Carbide or Diamond) at the end of the piston. The insert is located at the contact face (i.e.
  • the insert may have protrusions or teeth which are able to repeatedly cut through lubricant, rock dust and/or residue and engage with the rock surface of the borehole.
  • the teeth have a pyramidal profile.
  • other profiles may be used.
  • the piston and/or the insert of the gripper may optionally be coated. This may allow the gripper to achieve a greater gripping effect than an uncoated gripper.
  • the gripper may be coated with a layer of diamond or superhard grit to increase the effective friction further.
  • the gripper may not comprise a piston and may comprise a different mechanism for gripping the borehole, such as an extending arm or linkage, or an inflatable or swellable element.
  • the anchor may allow for a continuous gripping action as the drillstring advances downhole in the borehole.
  • a first gripping segment (or first set of gripping segments) or a part thereof can move longitudinally relative to a second gripping segment (or second set of gripping segments) or a part thereof.
  • the first and second gripping segments (or sets of gripping segments) are coupled to each other such that the first gripping segment (or set of gripping segments) or part thereof is free to move along the longitudinal axis of the anchor relative to the second gripping segment (or set of gripping segments) or part thereof.
  • the anchor comprises a drive mechanism for advancing the first gripping segment (or set of gripping segments) or part thereof downhole relative to at least the second gripping segment (or set of gripping segments) or part thereof.
  • the transition includes the coordinated gripping and release of gripping segments and may use a drive mechanism that is different to when only one gripping segment (or set of gripping segments) is activated.
  • the transition may be initiated in dependence on the position of the drillstring, for example relative to the activated gripping segment (or set of gripping segments), in dependence on elapsed time since a gripping segment (or set of gripping segments) was activated, or by some other means.
  • the drillstring and a second gripping segment are driven to progress them downhole.
  • the second gripping segment (or set of gripping segments) progress at a different (faster) speed than the drillstring, for example at twice the ROP of the drill bit;
  • -a second gripping segments (or set of gripping segments) is activated to grip the borehole; -the first gripping segment (or set of gripping segments) is deactivated and driven to progress down the borehole at a faster speed than the drillstring.
  • the anchor may comprise a means of or mechanism for advancing deactivated gripping segments downhole at a higher rate than the advancement of the drillstring in the borehole (for example, at twice the ROP of the drill bit).
  • grippers or gripping segments may be multiple grippers or gripping segments along the length of the anchor. There may be multiple grippers distributed around the circumference of the gripping segment. For example, there may be three or four rows of twenty gripping assemblies.
  • the anchor and/or other components in the BHA may comprise one or more devices for measuring one or more of torque, radial force, axial force and pressure, or for measuring one or more parameters that can be used to derive such quantities.
  • the measurement devices may comprise sensors, such as torque sensors, pressure sensors and axial force sensors, such as strain gauges.
  • the devices may also measure other parameters which may be used to infer the value of torque, radial force, axial force and/or pressure.
  • the devices may comprise mechanical or hydromechanical mechanisms that are configured to change state or move in response to variations in parameters such as torque, weight and pressure. That change or state or movement may be used to control or provide feedback to control the operation of the anchor.
  • the data may also be used to control the operation of the anchor, for example to control the operation of the gripper(s) or to control the axial force applied to the BHA, the drill bit or the drillstring.
  • Exemplary configuration allowing longitudinal force to be applied by the anchor to a distal tool
  • the flow of drilling fluid through the anchor may be used to provide the longitudinal force applied to the distal tool. This may also be used to apply a longitudinal force in the uphole direction.
  • the pressure difference between the drilling fluid being pumped down the inside the anchor (for example, through a central channel in the anchor) and the drilling fluid returning to surface in the annular space around the outside of the anchor can be used to perform work. This pressure difference can typically be many 100s of psi.
  • the higher-pressure drilling fluid from the inside of the tool can be directed (via valves or other means) to one side of an axial piston and the lower pressure annular drilling fluid can be directed (via valves or other means) to the other side of an axial piston.
  • the anchor may comprise an axial piston, or multiple axial pistons.
  • the or each axial piston may be connected to the gripping segment(s) and/or the drillstring via the shaft of the anchor.
  • FIG. 4a shows the configuration of the anchor when a longitudinal force is not applied to urge the drill bit 108 against the bottom (i.e. the distal end) of the borehole
  • FIG. 4b shows the configuration of the anchor when a longitudinal force is applied to urge the drill bit 108 against the bottom of the borehole.
  • the anchor comprises one or more gripping segments, each comprising one or more grippers.
  • One gripper is indicated at 401 .
  • An axial piston is shown at 402.
  • the chambers 403, 404 can be in fluid communication with the fluid passing through the anchor (for example, through the shaft 405, which can move with the drillstring) or the fluid in the annulus of the borehole.
  • the supply of fluid to the chambers 403, 404 can be controlled by valves or some other means.
  • the gripper 401 is engaged with the borehole wall.
  • FIG.s 4a and 4b the gripper 401 is engaged with the borehole wall.
  • the higher-pressure drilling fluid from the channel inside of the anchor is directed (via valves or other means) to the chamber 404 on the lower side (with respect to the bottom of the borehole) of the axial piston and the lower pressure annular drilling fluid can be directed (via valves or other means) to the chamber 403 on the upper side (with respect to the bottom of the borehole) of the axial piston.
  • the higher-pressure drilling fluid from the inside of the anchor is directed (via valves or other means) to the chamber 403 on the upper side (with respect to the bottom of the borehole) of the axial piston and the lower pressure annular drilling fluid can be directed (via valves or other means) to the chamber 404 on the lower side (with respect to the bottom of the borehole) of the axial piston.
  • the resulting imbalance in fluid force either side of the piston will result in movement of the piston in the downhole direction. This can be used to apply a longitudinal force to the downhole tool via the drillstring, for example through the shaft 405 passing through the anchor.
  • the apparatus can conveniently be used with coiled tubing (including with torsional and/or axial anchoring).
  • the application of longitudinal force by the anchor can replace the loads/forces typically coming from segment drill pipe in instances where drilling with coiled tubing is advantageous.
  • the system can also make control/decisions downhole without involving surface people/systems if desired.
  • the portion of the drillstring shown at 102 comprises a continuous work string in the form of coiled tubing.
  • the drillstring may be any other pipe, hose or transfer line for deploying drilling eguipment and the features described below may also apply to drillstrings having other forms.
  • the coiled tubing extends from the surface of the borehole.
  • the coiled tubing is attached to a coiled tubing connector coupled to the anchor by a rotatable coupling.
  • the rotatable coupling may not be present and the connector may be immediately proximal of the proximal end of the anchor, or may be separated from the anchor by other components, such as a sub or drill pipe.
  • the connector is proximal of the anchor in the drillstring.
  • the coupling 114 is a swivel.
  • the swivel may be a continuous swivel.
  • Other suitable couplings may be used.
  • the coupling is configured to at least partially isolate the connector from torsional forces generated distally of the anchor, for example from components to which the anchor is coupled in the BHA, such as the drill bit.
  • the coupling may be configured to fully isolate the connector (and thus the continuous work string attached to the connector in use) from torsional forces generated distally of the anchor.
  • the coupling is configured to allow relative rotation of the coiled tubing connector and the anchor about one or more axes.
  • the coupling may be immediately proximal of the proximal end of the anchor (i.e. immediately above I upbore of the anchor in the drillstring).
  • the coupling 114 comprises upper 114a and lower 114b parts.
  • the upper and lower parts of the coupling are configured to rotate relative to each other. Relative rotation may be allowed in both directions or in one direction only (for example, for a unidirectional swivel).
  • the lower part 114b is rotationally fast with the body of the anchor and the upper part 114a is rotationally fast with the connector.
  • the connector may be rotationally fast with the continuous work string when the work string is connected to the connector.
  • the rotatable coupling may be selectively rotatable. For example, it may be lockable so that the parts cannot rotate relative to each other when desired. The direction of rotation may also be controlled.
  • the coupling may also be axially compliant.
  • the axially compliant coupling may be configured to compress and/or extend in the axial direction, along the longitudinal axis of the borehole. This may allow the tool at the distal end of the drillstring to be able to progress in the wellbore in the event that the continuous work string becomes temporarily stuck or is not able to keep up with the rate of penetration of the drill bit.
  • the anchor may comprise the rotatable and/or axially compliant coupling at its proximal end (with respect to the surface when in use).
  • the coupling may be integrated with the anchor. That is, the body of the anchor and the coupling may be integrally formed. In other examples, the anchor and the coupling may be separate components with separate bodies.
  • the coupling may be proximal of the proximal end of the anchor and in some cases may be immediately proximal.
  • the connector 115 may be axially coupled with the drillstring below the anchor.
  • the anchor may be configured so that the portion of the drillstring above the anchor and the components of the BHA below the anchor can move axially relative to the body of the anchor when one or more of the grippers of the anchor is gripping the wellbore. This can allow the drilling, or other operation, to progress when the anchor is activated to grip the borehole.
  • the connector and the coupling may be configured to allow fluid to pass from the continuous work string to the anchor.
  • the upper 114a and lower 114b parts of the coupling may comprise respective flanges that are sealed together to prevent leakage of fluid whilst allowing relative rotation between the parts 114a, 114b.
  • the connector may be capable of applying or transferring axial force to the drillstring to pull the drill string down the borehole and/or push the drillstring up the borehole.
  • the anchor may be capable of applying or transferring axial force to the drillstring to pull the drillstring down the borehole and/or push the drillstring up the borehole.
  • the axial force may be generated by the anchor as described above. This can advantageously allow the anchor to act as a tractor for pulling the drillstring into and out of the borehole.
  • the connector may comprise one or more electrical connectors for connecting to one or more electrical cables within the drillstring for supplying electrical power to the apparatus from the surface of the borehole.
  • the connector may also comprise one or more data connectors for connecting to one or more data cables within the drillstring for transmitting bi-directional communications between the surface of the borehole and the anchor.
  • the anchor is communicatively connected with a control arrangement arranged for controlling the anchor.
  • the anchor may comprise the control arrangement, or the control arrangement may, for example, be located at the surface of the borehole or elsewhere within the downhole apparatus or BHA.
  • control arrangement may comprise a control unit 600.
  • An example of a control unit 600 and some of its associated components is shown in more detail in FIG. 6.
  • the control unit comprises a processor 601 and a memory 602.
  • the control unit may comprise more than one processor and/or more than one memory.
  • Each processor and memory may be at a different location.
  • one or more processor and/or memory may be at the surface of the borehole and/or one or more processor and/or memory may be at the BHA or anchor.
  • the processor may execute computer code stored at the memory 602 to perform the functions described herein.
  • the control unit 600 may control the anchor (for example, the configuration of one or more grippers of the anchor to control the axial and/or torsional force exerted against the borehole or to the drillstring below the anchor by the one or more grippers) based on control signals from a downhole processor. This can allow for autonomous control and/or kinematics control of the anchor and other components in the BHA.
  • the control unit may also comprise a transceiver 603 for sending and receiving signals to and/or from other entities, such as sensors communicatively connected to the anchor.
  • the control unit 600 can control the grippers of gripping segments 201 , 202 and can allow for standalone operation (i.e. with no connection of the control unit to surface).
  • the anchor control unit may also interface with an MWD module in the drillstring (for example to allow real-time feedback to an operator at the surface), and/or with E-line and/or wired drill pipe (for real-time two-way communications with the surface).
  • control unit 600 comprises one or more sensors 604.
  • the sensor(s) 604 may comprise, or the control unit 600 may be communicatively connected with, a vibration sensor configured to detect vibration transverse to the longitudinal axis of the drillstring, as will be described in more detail below.
  • the control unit 600 may also be connectable to other components of the BHA.
  • the BHA may comprise a steering device 112, such as an orienter or an RSS.
  • the use of a downhole control unit 600 can also allow high-speed well directional data to be transmitted to the steering device by sending control signals from downhole control unit 600.
  • the processor 601 of the control unit 600 of the anchor may be configured to execute a control strategy to vary the axial push/pull force applied to components proximal or distal of the anchor (for example, to the drillstring to push or pull it down the borehole or to the BHA or bit, for example to apply WOB) to improve or optimize the drilling process and reduce drilling dysfunction by reducing stick-slip by reacting torsional loads to the borehole.
  • the controller may vary the force based on axial or torsional loads measured at the anchor.
  • the controller may control the anchor and/or other components in the BHA based on closed loop feedback from downhole sensors to improve or optimize the drilling process.
  • the incorporation of the downhole control unit 600 comprising a processor 601 and memory 602 into the apparatus may also enable event and diagnostic analysis, as well as closed- loop control of the anchor downhole.
  • the BHA may comprise multiple anchors.
  • one anchor may comprise a master controller.
  • Each further anchor may comprise a slave controller.
  • the master controller may send control signals to the or each slave controller to allow the or each slave controller to control its respective anchor. This may allow, for example, one or more anchors to be controlled such that their respective gripper(s) is/are gripping the wellbore and one or more anchors to be controlled to operate a walking mechanism so that those one or more anchors can move longitudinally relative to the one or more anchors whose respective gripper(s) is/are gripping the wellbore.
  • the master controller and the slave controller(s) may each have the components described with respect to FIG. 5, such as one or more processors and one or more memories.
  • a processor may be part of a digital control arrangement that executes computer code to enact the desired control function.
  • Alternative control arrangements may be used in dependence on requirements. For example, for higher temperatures in geothermal drilling, which may be encountered at greater drilling depths, it may be desirable to use an analogue electronic circuit to control the apparatus. This may use passive components with higher temperature ratings than a digital control unit.
  • a mechanical or fluid-operated hydraulic control arrangement may alternatively be used, for example at even higher temperatures.
  • a valve and shuttle/track arrangement could control the applied longitudinal force based on the differential pressure of fluid (for example drilling mud) flowing through the anchor and the annulus of the wellbore.
  • digital logic circuitry analogue circuitry
  • valves that are triggered by, either directly or through hydraulic fluid, by the mechanical state of the equipment.
  • the drillstring terminates in a distal tool, such as a drill bit.
  • the anchor is communicatively connectable with a control arrangement, such as a processor that may be programmed to execute a predetermined control strategy.
  • the control arrangement may (for example, by execution of the control strategy by the processor) control the apparatus to apply longitudinal force to the distal tool to adjust or vary engagement between the distal tool and the borehole.
  • control arrangement may control the apparatus to adjust the depth of cut (DOC) made by the distal tool.
  • the DOC determines the amount of material removed per rotation of a drill bit.
  • the torque on bit (TOB) is determined by the DOC and the compressive strength of the formation.
  • the control arrangement may, knowing the relationship between WOB and DOC, control the WOB applied to the drill bit to achieve a desired DOC.
  • the processor may (for example by executing a control strategy) control the downhole apparatus to apply longitudinal force to the distal tool to maintain engagement between the distal tool and the borehole.
  • the control arrangement may control the downhole apparatus to increase the longitudinal force applied by means of the anchor to the distal tool to maintain engagement between the distal tool and the borehole.
  • Drilling dysfunction such as stick-slip
  • ROP may be significantly improved.
  • Use of the anchor may thus reduce severity of stick-slip and/or allow drill bits to drill further and faster through improved engagement of the bit with the rock.
  • control arrangement may receive one or more downhole parameter measurements, such as downhole pressure, WOB and/or torque, from the one or more downhole sensors and control the anchor to apply longitudinal force to the distal tool in dependence on the one or more downhole parameter measurements.
  • downhole parameter measurements such as downhole pressure, WOB and/or torque
  • control arrangement is configured to determine one or more downhole parameter measurements from the inputs received from the one or more downhole sensors and control the anchor to apply longitudinal force to the distal tool in dependence on the one or more downhole parameter measurements.
  • WOB mode can utilize feedback from a WOB sensor (or from other sensors from which WOB can be determined or inferred) to control axial thrust to stabilize WOB, or longitudinal force on another downhole tool at the distal end of the drillstring for a more consistent downhole process.
  • the ability to modulate WOB may address a major source of drilling dysfunction.
  • the drillstring comprises a rotational drive, such as a motor 110, proximal of the distal tool 108 for driving the distal tool to rotate.
  • the control arrangement may control the longitudinal force applied to the distal tool 108 to maintain the rotational drive within one or more predetermined operational ranges.
  • a processor may be configured to execute the control strategy to control the longitudinal force applied to the distal tool 108 to maintain the rotational drive within one or more predetermined operational ranges.
  • the one or more predetermined operational ranges may be predetermined ranges of one or more of rotational speed, torque and power of the rotational drive.
  • the drillstring terminates in a distal tool, such as a drill bit.
  • the downhole apparatus comprises an anchor having a gripper for engaging the borehole to restrict relative axial and/or rotational movement between the gripper and the borehole.
  • the anchor may be communicatively connectable with a control arrangement arranged for controlling the apparatus to, in response to the detection of a condition associated with a reduction in drilling efficiency and/or a condition associated with damage to the drillstring, adjust longitudinal force applied by means of the anchor to the distal tool.
  • Examples of conditions associated with a reduction in drilling efficiency and/or damage to the drillstring may include stick-slip or the presence of other longitudinal or torsional vibrations, which may be detected using downhole sensors, such as vibration sensors or torque sensors on the drillstring or distal tool.
  • the processor may detect a condition associated with a reduction in drilling efficiency and/or damage to the drillstring when the vibration of the drillstring or distal tool exceeds a predetermined threshold.
  • Adjusting the longitudinal force applied by means of the anchor to the distal tool may comprise increasing the longitudinal force applied by means of the anchor to the distal tool. This may help to achieve consistent engagement between the distal tool and the borehole. Where the distal tool is a drill bit, this may result in faster drilling. Alternatively, the applied longitudinal force may be reduced.
  • the drillstring comprises a rotational drive proximal of the distal tool for applying rotational drive to the distal tool.
  • the control arrangement may, in response to the detection of a condition associated with a reduction in drilling efficiency or a condition associated with damage to the drillstring, adjust the longitudinal force applied by means of the anchor to the distal tool to stabilize or optimize requirements (such as torque requirements) of the rotational drive and/or stabilize rotational output from the rotational drive.
  • the anchor can adjust the longitudinal force applied to the drill bit to stabilize or modulate the depth of cut.
  • the torque required to rotate the drill bit is proportional (although may not be linear) to the depth of cut of the drill bit and depth of cut is proportional to the WOB applied to the drill bit. Adjusting the longitudinal force applied to the drill bit can adjust the torque required or rotational speed of the rotational drive and this WOB, depth of cut, torque and/or speed relationship can also be used to damp I cancel out torsional oscillations of the drillstring.
  • the control arrangement may be arranged to control the rate of penetration (ROP) of the distal tool.
  • the control arrangement may, knowing the relationship between WOB and ROP, control the WOB applied to the drill bit to achieve a desired ROP. This may allow multiple downhole control options to be implemented.
  • the anchor may comprise a linear position sensor to measure the relative displacement between one or more gripping segments of the anchor and a component that is axially fast with the distal tool (i.e. that moves axially with the distal tool), such as the shaft passing through the anchor.
  • the linear sensor can be configured to derive the ROP of the distal tool using this position measurement.
  • the control arrangement may be configured to determine whether a predetermined ROP of the distal tool has been achieved in dependence on measurements acquired by the linear position sensor.
  • the control arrangement may control the longitudinal force applied to the distal tool to achieve a target ROP as determined by the position sensor.
  • the processor or other control arrangement is a downhole control arrangement at the anchor, the proximity of the control arrangement to the drill bit or other distal tool may result in improved control performance.
  • the drillstring comprises a rotational drive.
  • the control arrangement can be configured to control the apparatus to (i) reduce the longitudinal force applied to the distal tool to reduce the torque on the rotational drive so as to maintain rotation of the distal tool or (ii) increase the longitudinal force applied to the distal tool to increase the torque applied by the rotational drive.
  • the control arrangement may be configured to detect an increased resistance being encountered by the distal tool in dependence on inputs from one or more downhole sensors local to the downhole apparatus, as described above.
  • the sensor(s) may be located at the control arrangement (i.e. sensors 604 of control unit 600) or may be other downhole sensors local to the apparatus and/or communicatively connected to the control arrangement.
  • control arrangement may maintain a rotational drive in the BHA at one or more predetermined operational values, or within one or more predetermined operational ranges.
  • the one or more predetermined operational values or ranges may be predetermined values or ranges of one or more of rotational speed, torque and power of the rotational drive. Operation at these values and/or within these ranges may prevent stalling of the rotational drive.
  • Motor stalls can occur when too much WOB is applied to the distal tool or drill bit. This can result in over engagement of the drill bit cutters and torque requirements that exceed the capacity of the rotational drive.
  • the differential pressure across the rotational drive in this example a positive displacement drilling motor, may significantly increase and in some cases result in a stall.
  • a stall may occur because the differential pressure exceeds the pressure capabilities of an internal seal between the rotor and stator and allows fluid to bypass the rotational drive element without translating into rotation of the drive.
  • the available power to turn the distal tool I drill bit reduces and the bit can stall. This can also damage the elastomers and mechanical components within the mud motor and the drilling assembly.
  • the circulation pressure in the run up to the stall event or during may be too high for the drilling fluid pumps at surface to continue to pump fluid at a sufficient rate to maintain the rotational speed of the mud motor.
  • the application of stable longitudinal force can prevent the initial over engagement of the drill cutters and prevent the torque increase/spike that results in motor stalling.
  • the ability to control longitudinal force in response to differential pressure can keep the drilling motor in its optimum power band and in such situations where an event occurs to over-engage the cutters with the formation, can reduce the longitudinal force rapidly to prevent stall and/or differential pressures that might damage elements within the drilling motor or drilling assembly.
  • Such operational ranges may be known by the control arrangement (for example, by the processor).
  • the anchor may comprise an internal channel for conveying the flow of drilling fluid to the distal tool.
  • the control arrangement may be configured to maintain a differential pressure between the channel and the annulus of the borehole within a predetermined range.
  • Controlling the differential, or delta, pressure (the difference in the pressure of drilling fluid within the anchor and in the annulus of the borehole) at the anchor for example using control flow valves to restrict the flow of drilling fluid through the anchor to reduce or increase the pressure differential, may be used to improve or optimize rotational drive (for example, drilling turbine or drilling motor) operation where the BHA comprises a rotational drive.
  • rotational drive for example, drilling turbine or drilling motor
  • Pressure feedback can be used to stabilize the rotational drive (turbine or motor) differential pressure, torque and/or DOC of the drill bit, which may help to significantly improve turbine/motor and drill bit life, whilst also resulting in higher ROP by allowing turbines or motors to be run closer to their maximum power.
  • fluid with increased or reduced pressure, as controlled by the anchor may be directed to bypass the rotational drive along a different flow path not passing the rotor of the motor, before being discharged through outlets at the distal tool.
  • the processor or other control arrangement is configured to determine the rotational speed of the rotational drive. One way in which this may be done will now be described.
  • the one or more downhole sensors may comprise a vibration sensor configured to detect vibration transverse to the longitudinal axis of the drillstring.
  • the vibration sensor may be, for example, a lateral accelerometer.
  • the processor may receive measurements of vibration transverse to the longitudinal axis of the drillstring (i.e. lateral vibration) from the sensor.
  • the rotational speed of the rotation drive can be determined in dependence on input received from the vibration sensor and a known configuration of the rotational drive.
  • the known configuration of the rotational drive may be a number of rotor lobes of the rotational drive.
  • the detected lateral vibration is approximately equal to the rotational speed of the rotational drive multiplied by the number of rotor lobes of the rotational drive.
  • the rotational speed of the rotational drive may be determined at the control unit by dividing the detected vibration by the number of rotor lobes of the rotational drive.
  • the one or more downhole sensors may alternatively or additionally comprise a pressure sensor located at the annulus of the borehole which can detect pressure pulses in fluid exiting the motor which are proportional to the motor speed.
  • a pressure sensor located at the annulus of the borehole which can detect pressure pulses in fluid exiting the motor which are proportional to the motor speed.
  • This may allow the rotational speed of the rotational drive to be determined downhole and used in control schemes to adjust the rotational speed or other downhole operational parameters. This also provides the ability to improve or optimize the performance of the rotational drive. Motor stall can greatly impact drilling efficiency and drilling dysfunction. Where the rotational drive is a mud motor, by keeping differential pressure within a predetermined range, instances of motor stall may be minimized.
  • the ability of the anchor to measure the rotational speed of a motor may also result in an improvement in motor performance by measuring motor RPM and controlling the motor downhole, which does not require MWD or other telemetry of RPM to the surface.
  • This provides the ability to improve bit performance by controlling longitudinal force applied to the distal tool (for example, WOB) and motor speed in real-time downhole. This can assist in avoiding a loss of control and delay resulting from the length/elasticity of the drillstring to the surface of the borehole.
  • WOB longitudinal force applied to the distal tool
  • motor speed in real-time downhole. This can assist in avoiding a loss of control and delay resulting from the length/elasticity of the drillstring to the surface of the borehole.
  • the downhole apparatus may operate according to multiple control modes.
  • the downhole apparatus may be controlled in response to downhole sensor measurement of differential pressure and/or torque. In another implementation, the downhole apparatus may be controlled in response to downhole sensor measurement of WOB or pressure at the distal tool. As mentioned above, in a further implementation, the downhole apparatus may be controlled in response to downhole sensor measurement of longitudinal displacement of one or more of the gripping segments relative to the body of the anchor or the shaft of the anchor. This may be used to estimate the ROP of the distal tool.
  • the control arrangement may be configured to determine whether a predetermined ROP of the distal tool has been achieved in dependence on measurements acquired by the linear position sensor. The control arrangement may control the longitudinal force applied to the distal tool to achieve a target ROP as determined by the position sensor.
  • the processor may control the application of longitudinal force on the distal tool in response to data received from the displacement sensor(s) to achieve a predetermined ROP of the distal tool.
  • control arrangement may be configured to control the apparatus to apply longitudinal force to the distal tool to achieve a predetermined WOB and/or TOB as measured by the sensor(s).
  • the downhole apparatus may comprise a drillstring (or drill bit) rotational speed sensor.
  • the control arrangement may be configured to receive data from the rotational speed sensor.
  • the control arrangement may be configured to control the apparatus to apply longitudinal force to the distal tool to achieve a predetermined rotational speed as measured by the sensor.
  • the downhole apparatus may first operate according to a primary control mode (for example, ROP mode) but may implement a different control mode (for example, using motor differential pressure/torque control) if the detected differential pressure of drilling fluid flowing through the tool exceeds a threshold.
  • a primary control mode for example, ROP mode
  • a different control mode for example, using motor differential pressure/torque control
  • the ROP mode may also utilize anchor traverse speed to control ROP, allowing for much more consistent drilling.
  • WOB and motor/bit interaction are likely a majority creator of slip-stick and controlling that interaction with WOB may help to eliminate its creation, and not just insulate the drillstring exaggeration or compounding of stick-slip.
  • Controlling and/or providing prime drilling forces, such as WOB and/or torque on bit, downhole instead of from surface may help to control or eliminate axial slip-stick deriving from drillstring.
  • This may be improved further by the addition of a shock sub (which may be a common shock sub or custom shock sub) proximal of the anchor in the drillstring.
  • the processor may be configured to execute an algorithm to control the anchor to apply longitudinal force to the distal tool in dependence on measurements acquired by one or more sensors, such as displacement, ROP, WOB, TOB and/or rotational speed.
  • the algorithm may be an efficiency algorithm that controls the longitudinal force applied to the distal tool to achieve the most efficient drilling based on the sensor measurements.
  • the application of longitudinal force by the anchor to the borehole can be used to withdraw one or more downhole tools from the borehole.
  • FIG. 7 shows a flow chart illustrating the steps of an exemplary method of performing a downhole operation in a borehole.
  • the downhole operation may be, for example, a drilling, milling, fishing, abandonment or completions operation, or any other downhole operation.
  • the method comprises performing a downhole operation using a drillstring comprising a downhole tool and an anchor having a gripper for engaging the borehole to react axial and/or rotational force between the anchor (for example, a gripper thereof) and the borehole.
  • the method comprises operating the anchor to move through the wellbore in a surface-bound direction so as to retract the downhole tool from the borehole.
  • the apparatus may be connected to further components suitable for performing the operation in the borehole, such as the components of the BHA described above.
  • the system described herein can operate as an autonomous system for drilling, milling, completions or other operations.
  • torsional stick slip and general drilling dysfunction can result from erratic weight transfer and movement of the drillstring into the borehole.
  • This erratic movement and transfer of force to the drill bit may result in irregular changes in depth of cut and therefore irregular drilling torque that can initiate and/or reinforce torsional dynamics including but not limited to stick slip.
  • Phenomena such as drillstring buckling
  • the drillstring may comprise an axially compliant member above the anchor.
  • the addition of an axially compliant member in the drillstring above the anchor can also help to damp movement and/or longitudinal force requirements of the anchoring system.
  • the application of longitudinal force to the drill bit by the anchor and movement may help to overcome erratic drillstring drag forces and stabilize and/or optimize the engagement of the distal tool with the borehole.
  • the inclusion of axial compliance above the anchor may damp drillstring movement and allow the anchor and the longitudinal force applied by it to the distal tool to stabilize WOB.
  • the application of longitudinal force may also assist in mitigating or minimizing buckling of the drillstring and increasing and/or optimizing and/or maximizing weight on the distal tool (for example, WOB).
  • a downhole control arrangement which may comprise a processor in some implementations, can allow for full kinematics control of processes downhole, for example to eliminate drilling dysfunctions (such as stick slip) and can also minimize the need for heavy drilling BHAs that typically limit the use of continuous work strings such as coiled tubing.
  • the anchor can advantageously isolate the drilling assembly and react torque to the formation, as well as applying axial (push/pull) forces to the work string, BHA and drill bit.
  • High fidelity and reliable real-time formation evaluation and drilling mechanics data can minimize drilling risk and allow for real-time closed loop control of parameters and drilling kinematics downhole. Improved well control and reduced chance of stuck pipe may result due to more reliable bottom hole pressure control.
  • the application of axial forces at the anchor may also allow the anchor to be used as a tractor for completions and intervention operations.
  • this may allow a continuous work string, such as coiled tubing, to remain in tension, which may significantly increase the drillable footage. This may also help to avoid buckling, which may occur in typical coiled tubing applications.
  • measurement devices such as sensors local to the anchor, for example at the anchor itself, to measure parameters such as torque and axial force, increased measurement density can allow more precise well placement and formation characterization.
  • Axial stick slip mitigation and/or control of drilling ROP can improve drill motor life due to more stable control of motor differential pressure and torque.

Landscapes

  • Engineering & Computer Science (AREA)
  • Life Sciences & Earth Sciences (AREA)
  • Geology (AREA)
  • Mining & Mineral Resources (AREA)
  • Physics & Mathematics (AREA)
  • Environmental & Geological Engineering (AREA)
  • Fluid Mechanics (AREA)
  • General Life Sciences & Earth Sciences (AREA)
  • Geochemistry & Mineralogy (AREA)
  • Mechanical Engineering (AREA)
  • Earth Drilling (AREA)

Abstract

L'invention concerne un appareil de fond de trou destiné à être utilisé dans un train de tiges de forage dans un trou de forage, le train de tiges de forage se terminant dans un outil distal, l'appareil de fond de trou comprenant un ancrage ayant un élément de préhension pour venir en prise avec le trou de forage pour faire réagir une force axiale et/ou de rotation entre l'ancrage et le trou de forage, l'ancrage pouvant être relié en communication avec un agencement de commande agencé pour, en réponse à la détection d'une condition associée à une réduction de l'efficacité de forage et/ou une condition associée à un endommagement du train de tiges de forage, commander l'appareil pour ajuster une force longitudinale appliquée au moyen de l'ancrage à l'outil distal.
PCT/EP2025/055722 2024-03-01 2025-03-03 Appareil de fond de trou destiné à être utilisé dans un trou de forage Pending WO2025181402A1 (fr)

Priority Applications (1)

Application Number Priority Date Filing Date Title
PCT/EP2025/073604 WO2026037967A1 (fr) 2024-08-16 2025-08-18 Outil de fond de trou et dispositif de commande destiné à être utilisé dans un trou de forage

Applications Claiming Priority (6)

Application Number Priority Date Filing Date Title
US202463560158P 2024-03-01 2024-03-01
US63/560,158 2024-03-01
GB2405172.4A GB2638791A (en) 2024-03-01 2024-04-11 Downhole apparatus for use in a borehole
GB2405172.4 2024-04-11
EPPCT/EP2024/080340 2024-10-25
PCT/EP2024/080340 WO2025088194A1 (fr) 2023-10-25 2024-10-25 Appareil de fond de trou destiné à être utilisé avec une colonne de travail continue

Publications (1)

Publication Number Publication Date
WO2025181402A1 true WO2025181402A1 (fr) 2025-09-04

Family

ID=94824166

Family Applications (1)

Application Number Title Priority Date Filing Date
PCT/EP2025/055722 Pending WO2025181402A1 (fr) 2024-03-01 2025-03-03 Appareil de fond de trou destiné à être utilisé dans un trou de forage

Country Status (1)

Country Link
WO (1) WO2025181402A1 (fr)

Citations (4)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
US20060054354A1 (en) * 2003-02-11 2006-03-16 Jacques Orban Downhole tool
US20100307832A1 (en) * 2000-12-01 2010-12-09 Western Well Tool, Inc. Tractor with improved valve system
US20150369030A1 (en) * 2013-12-20 2015-12-24 Halliburton Energy Services, Inc. Closed-loop drilling parameter control
EP3186465B1 (fr) * 2014-08-26 2020-03-25 Baker Hughes, a GE company, LLC Moteur de fond de trou pour des applications à portée étendue

Patent Citations (4)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
US20100307832A1 (en) * 2000-12-01 2010-12-09 Western Well Tool, Inc. Tractor with improved valve system
US20060054354A1 (en) * 2003-02-11 2006-03-16 Jacques Orban Downhole tool
US20150369030A1 (en) * 2013-12-20 2015-12-24 Halliburton Energy Services, Inc. Closed-loop drilling parameter control
EP3186465B1 (fr) * 2014-08-26 2020-03-25 Baker Hughes, a GE company, LLC Moteur de fond de trou pour des applications à portée étendue

Similar Documents

Publication Publication Date Title
US9482054B2 (en) Hole enlargement drilling device and methods for using same
US8636086B2 (en) Methods of drilling with a downhole drilling machine
CA2776610C (fr) Trepans de forage et procedes de forage de trous de forage devie
WO2007103245A2 (fr) Procédés et dispositif de forage d'agrandissement de trou orientable et automatique
WO2023152404A1 (fr) Ancrage d'une garniture de forage
EP1780372B1 (fr) Système de forage
US11643883B1 (en) Adjustable flex system for directional drilling
CA2861177C (fr) Systeme de traction a piston a utiliser dans des puits souterrains
JP2011504212A (ja) 掘削システム
EP3186465B1 (fr) Moteur de fond de trou pour des applications à portée étendue
EP4665943A1 (fr) Ancrage d'une garniture de forage
WO2025181402A1 (fr) Appareil de fond de trou destiné à être utilisé dans un trou de forage
GB2638791A (en) Downhole apparatus for use in a borehole
WO2025088194A1 (fr) Appareil de fond de trou destiné à être utilisé avec une colonne de travail continue
GB2636344A (en) Downhole apparatus for use with a continuous work string
WO2026037966A1 (fr) Système de fond de trou destiné à être utilisé dans un trou de forage
WO2026037967A1 (fr) Outil de fond de trou et dispositif de commande destiné à être utilisé dans un trou de forage
US20160237748A1 (en) Deviated Drilling System Utilizing Force Offset
GB2378468A (en) Electrically sequenced tractor
EP4479618A1 (fr) Ancrage d'une garniture de forage
GB2615620A (en) Drillstring anchor

Legal Events

Date Code Title Description
121 Ep: the epo has been informed by wipo that ep was designated in this application

Ref document number: 25708800

Country of ref document: EP

Kind code of ref document: A1