This application claims the benefit of GB Patent Application No. 1022040.8, filed on Dec. 29, 2010, the entire contents of which are hereby incorporated by reference.
The invention relates to a downhole tool and in particular, but not exclusively, to a large gauge concentric reamer or underreamer. The invention also relates to methods of using the downhole tool.
Bores are drilled from the surface for various purposes, such as exploration and production in the oil and gas industry. Bores may be formed with drills of an initial diameter and subsequently enlarged. For example, an initial narrow bore may be made when all characteristics of the formation to be drilled are not known, such as whether gas could be encountered whilst drilling. Upon completion of the narrow borehole, a desired greater final bore diameter may be safely achieved by a reaming operation. In other instances the initial bore diameter may be less than desired, such as due to wear of a drill bit, or encroachment by material adjacent the bore (e.g. plastic formation creep).
Bores are often lined, such as with sections of casing in the oil and gas industry to provide a continuous fluid-tight conduit for conveying fluids through the bore. Typically the casings are fixed in place by injecting cement in an annular space between the casing and the bore wall. Once a first section of bore has been lined, a subsequent section is bored, involving passing the drill bit through the casing. Consequently the drill bit has a smaller diameter than the casing and in order to drill a bore at a larger diameter, such as the same diameter of the first section of bore, an under-reamer is often mounted above the drill bit.
In addition to continuous sections of larger diameter, reamers may be used to create localized sections of larger diameter. For example, where a feature in a bore is to be placed, such as a branch or deviation, the bore diameter may be focally enlarged.
Tools used for reaming operations comprise extendable cutters that are actuated to project out from the diameter of the main body of the tool to enlarge the bore diameter. Typically the cutters are also retractable for subsequent passage through a narrower section, such as for retrieval through casing. The extent to which the cutters can extend limits the maximum diameter that can be reamed. In order to increase the maximum reamable diameter, hinged cutters are used; however the hinged constructions are relatively weak and the hinged cutters can fail leading to costly interruptions and retrieval operations.
According to an aspect of the invention there is provided a downhole tool comprising:
a body comprising a throughbore;
at least one extendable cutting member; and
an actuation member operatively associated with the extendable cutting member and movable relative to the body to extend the cutting member laterally from the body along an extension axis;
wherein the extension axis is offset from a radius of the body.
Providing a downhole tool with an offset extendable cutting member enables the cutting member to be optimised for rotation of the downhole tool in a particular direction. This may be useful in circumstances where it is desired to increase the extendable length of the cutting member, such as to ream, or underream, a large gauge.
The tool may be a reamer or an undereamer, such as a concentric underreamer.
The tool may comprise a stabilizer.
The cutting member may be a cutter block, such as of a fixed block type. Downhole tools, such as reamers, with block cutters are generally more reliable and stronger than downhole tools, such as reamers, with hinged cutting members. An orientation of the cutting member relative to the body may be substantially the same in the unextended and extended configurations. For example, the longitudinal axis of the cutting member may be substantially parallel to the downhole tool longitudinal axis in the unextended and extended configurations. The orientation of the cutting member relative to the body may remain substantially the same during reconfiguration(s) between the unextended and extended configurations.
The tool may be configured to extend the cutting member laterally by sliding the cutting member along the extension axis. The body may comprise a window, the window configured for the cutting member to slide through to extend and/or retract. The cutting member may be configured to extend laterally by translation through the window.
The cutting member may comprise an offset recess for accommodating the throughbore in an unextended configuration.
The cutting member may comprise a retention portion, such as a dovetail, for retaining the cutting member to the actuation member, the retention portion being offset from the extension axis. The cutting member may comprise a single retention portion.
The cutting member may be arranged about a central axis in a direction of extension of the cutting member. The extension axis may comprise the central axis. The cutting member central axis may be offset from a central longitudinal axis of the downhole tool.
The cutting member may be offset from a central longitudinal axis of the body.
The extension axis may be offset from a central longitudinal axis of the body. The extension axis may be in a plane perpendicular to the longitudinal axis of the body. For example, the extension axis may be collinear with a non-radial chord of the body. The extension axis may be parallel to the radius of the body. Alternatively, the extension axis may be angularly offset from the radius. The extension axis may be in a non-perpendicular plane. For example, the extension axis may be offset from the radius, such as along a non-radial chord, and also at angle relative to the longitudinal axis of the tool, such as inclined towards a downhole direction.
The cutting member central axis may be parallel to the radius of the downhole tool. The cutting member central axis may be angularly offset from the radius. For example, the cutting member central axis may be collinear with a non-radial chord of the body.
The cutting member central axis may be parallel to the radius of the body. The cutting member central axis may be in a plane perpendicular to the longitudinal axis of the body.
The actuation member may be configured to extend multiple cutting members simultaneously. The actuation member may be a cam member. The downhole tool may be configured to extend the cutting member by movement of the actuation member in the longitudinal direction of the downhole tool.
The cutting member may comprise multiple cutting elements.
The cutting elements may be arranged in rows. A first row may be located on a first side of the cutting member central axis and a second row may be located on a second side of the cutting member central axis.
The cutting member may be configured such that the cutting member central axis, or an extrapolation thereof, does not intersect the downhole tool central longitudinal axis.
The cutting member central axis may be colinear with a portion of a non-radial chord of a cross-section substantially perpendicular to the longitudinal axis of the downhole tool.
According to an aspect of the invention there is provided a downhole tool with at least one extendable cutting member for reaming a bore, the cutting member comprising a first side portion and a second side portion; wherein the first side portion is substantially greater than the second side portion.
Providing a downhole tool with an extendable cutting member that has a first side portion greater than a second side portion enables the cutting member to be optimised for rotation of the downhole tool in a particular direction. This may be useful in circumstances where it is desired to increase the extendable length of the cutting member.
The first side portion being substantially greater than the second side portion may comprise the first side portion being longer than the second side portion in a direction of extension of the cutting member. The direction of extension may be along an extension axis. The first side portion may be arranged on a first side of the extension axis and the second side portion may be arranged on a second side of the extension axis.
The first side portion may be substantially greater than the second side portion at a position along the cutting member's axial length. The longitudinal axis of the cutting member may be substantially parallel to a longitudinal axis of the tool.
The first side portion may be substantially greater than the second side portion substantially along the axial length of the cutting member.
The longitudinal axis of the cutting member may be substantially perpendicular to the direction of extension of the cutting member.
The extension axis may be offset from a central longitudinal axis of the downhole tool.
Alternatively, the extension axis may intersect the central longitudinal axis of the downhole tool.
The first side portion may extend further than the second side portion in the direction of extension.
The first side portion may be substantially greater than the second side portion at a cross-section through the cutting member, the cross-section perpendicular to the cutting member's longitudinal axis.
The cross-section may be asymmetrical about the extension axis.
The first side portion may be a forward side portion in a direction of rotation of the tool. Alternatively, the first side portion may be a rearward side portion in a direction of rotation of the tool.
The first side portion may be on a first side of a cutting member plane and the second side portion may be on a second side of the cutting member plane.
The cutting member plane may be parallel to the direction of extension and parallel to the longitudinal axis of the tool.
The cutting member plane may intersect a center of the cutting member.
The downhole tool may further comprise a main body, the main body configured to receive the cutting member.
The first and/or second side portions may be configured to transfer load between the cutting member and the main body.
The first and/or second side portions may be configured to support the cutting member, such as during rotation of the tool. For example the first side portion may comprise a first support face. Additionally, or alternatively, the second side portion may comprise a second support face.
The first support face may be configured to abut a first receiving face of the main body. The second support face may be configured to abut a second receiving face of the main body.
The downhole tool may further comprise a central longitudinal member, such as a throughbore.
The length of the first side portion may be greater than a radial distance between the central longitudinal member and an external diameter of the main body.
The cutting member may further comprise a cutting portion and a rear portion, the rear portion distal from the cutting portion in the direction of extension of the cutting member.
The cutting member may be configured to position the rear portion rearwards of the centre of the downhole tool in an unextended configuration.
Rearwards is understood to be a direction substantially opposite to the direction of extension.
Providing a cutting member with a rear portion positioned rearwards of the center of the downhole tool in an unextended configuration enables the cutting member to have an increased length in the direction of extension. An increased length in the direction of extension allows an increased maximum diameter of a reamed bore; in particular, relative to the diameter of the downhole tool. The increased length may be relative to a cutting member with a rear portion aft of the center of the downhole tool in an unextended configuration.
The direction of extension may be substantially radial with respect to the longitudinal axis of the downhole tool.
The longitudinal axis of the downhole tool may be configured to be substantially parallel to the bore.
The direction of extension may be angled with respect to the longitudinal axis of the downhole tool. For example, the direction of extension may be substantially radial when viewed in a cross-section perpendicular to the longitudinal axis of the tool. Additionally, or alternatively, the direction of extension may be at an angle between 0 and 90 degrees when viewed in a cross-section parallel to the longitudinal axis of the tool.
The extension axis may be a central extension axis, passing through the center of the cutting member. The center of the cutting member may be located equidistant to the first and second side portions of the cutting member when viewed in a cross-section perpendicular to the longitudinal axis. The cross-section may be at a location along the longitudinal axis, such as at a leading end region.
The extension axis may be linear. The extension axis may be substantially perpendicular to the downhole tool longitudinal axis. The extension axis may be substantially straight. Alternatively, the extension axis may be curved; such as a helical axis. The helical axis may be a cylindrical helical axis. Additionally or alternatively the helical axis may be a conical helical axis.
The cutting member may be configured to position the rear portion rearwards of a downhole tool central plane, the central plane substantially perpendicular to the direction of extension and extending along the central longitudinal axis of the downhole tool.
The rear portion may be at a longitudinal region of the cutting member.
For example, the rear portion may be located towards a leading end of the cutting member.
A dimension of the cutting member in the direction of extension may be greater than a radius of the downhole tool. The radius of the downhole tool may be an external radius, such as a distance from the central longitudinal axis of the tool to an external portion of the tool. Additionally or alternatively, a dimension of the cutting member in a plane perpendicular to the longitudinal axis of the downhole tool may be greater than the radius of the downhole tool.
The dimension may be a distance between a foremost portion of the cutting member and an aft portion of the cutting member in the direction of extension (e.g. a length/height).
The dimension may be a distance in the direction of extension between projections in the downhole tool axial direction of a foremost portion of the cutting member and an aft portion of the cutting member (e.g. a total length/total height).
The cutting member may be configured to position the rear portion adjacent the central longitudinal member in the unextended configuration at least one point along the length of the cutting member in the longitudinal direction of the downhole tool.
At the at least one point along the length of the cutting member in the longitudinal direction of the downhole tool, the rear portion may be configured to substantially overlap the central longitudinal member in the direction of extension in the unextended configuration.
The cutting member may comprise a support portion.
The support portion may comprise the rear portion.
The support portion may be configured to maintain the angular position of the cutting member during a reaming operation. For example, the cutting member support portion may be configured to transfer rotational force between the cutting member and the main body.
The support portion may be configured to support the cutting member in the tool when the tool is rotated, such as during a cutting or reaming operation. For example, the support portion may comprise an asymmetrical cross-section in a plane perpendicular to the longitudinal axis.
The main body may be configured to support the cutting member when the tool is rotated. For example, the main body may comprise a support portion, the support portion including a support face for contacting a corresponding portion of a cutting member, such as a face corresponding to the first side portion of the cutting member.
The support face may have a greater cross-sectional length, such as a length or height in the direction of extension, than a radial thickness of the main body. For example, the support face may have a greater cross-sectional length than a radial distance between the central longitudinal member and the external diameter of the main body. For example, a radial separation of the throughbore from the external diameter of the main body.
The support face may extend further than the radius of the downhole tool on the unextended configuration.
Providing a tool with a main body with a support face that is longer in a plane perpendicular to the longitudinal axis of the tool helps to provide rotational support to the cutting member when the tool is rotated about its longitudinal axis, such as during a reaming operation. Similarly, providing a cutting member with a greater support portion length in an extension plane perpendicular to the longitudinal axis provides more rotational support during rotation of the tool.
The support face may be planar.
Additionally or alternatively, the support face may be curved (e.g. helically curved).
The cutting member may be configured in the unextended configuration to receive a second cutting member. For example, a first cutting member may comprise a recess, the recess configured to receive a rear portion of the second cutting member in the unextended configuration.
The first and/or second portion(s) may be configured to receive a rear portion of a second cutting member. For example, the side portion may comprise the recess.
The second side portion of the first cutting member may be configured to receive a first side portion of the second cutting member in the unextended configuration.
The main body may be configured to receive multiple cutting members.
For example, the main body may be configured to receive two cutting members.
The cutting member rear portion may have an asymmetrical cross-section about the central axis of extension, the cross-section in a plane perpendicular to the longitudinal axis of the tool. The multiple cutting members may be arranged substantially in a plane perpendicular to the downhole tool longitudinal axis. The multiple cutting members may be arranged at substantially the same axial position along the downhole tool longitudinal axis. For example, the downhole tool may comprise three cutting members, the cutting members arranged evenly around the downhole tool central longitudinal axis at a predetermined position. Providing three cutting members circumferentially arranged provides a self-centering tool such that a bore may be concentrically enlarged by a reaming process. The longitudinal position of the cutter(s) may vary with respect to the main body; for example when the cutter(s) are retracted and/or extended.
The cutting member may be configured to be rotationally driven in a particular direction. For example, the cutting member may comprise a greater strength and/or stiffness in a particular direction of rotation, such as clockwise. The actuation member may be configured to support the cutting member for drive in a particular direction. For example, the actuation member may comprise a greater strength and/or stiffness in a particular direction of rotation, such as clockwise.
The asymmetrical cross-section may provide for an asymmetrical retention element(s). For example, the cutting member may comprise a single dovetail for retaining the cutting member to the actuation member. The asymmetrical element(s) may provide for optimization of the cutting member for rotation in a particular direction, such as in the direction of the element(s).
Each cutting member may be configured to receive a first side portion of another cutting member in the unextended configuration.
Each cutting member may be configured to receive a rear portion of another cutting member in the unextended configuration.
According to an aspect of the invention there is provided a method of operating a downhole too), the method comprising:
providing a downhole tool comprising:
moving the actuation member relative to the body to extend the cutting member laterally from the body along the extension axis.
The method may comprise moving the actuation member relative to the body to retract the cutting member.
According to an aspect of the invention there is provided a method of reaming a bore, the method comprising
providing a downhole tool comprising a main body and a cutting member, the cutting member comprising a cutting portion and a rear portion, the rear portion distal from the cutting portion in a direction of extension of the cutting member,
configuring the cutting member in an unextended configuration, wherein the rear portion is positioned rearwards of the center of the downhole tool,
reconfiguring the cutting member in an extended configuration, wherein the cutting portion extends radially beyond the main body,
rotating the tool.
According to an aspect of the invention there is provided a method of reaming a bore, the method comprising:
providing a downhole tool comprising:
configuring the cutting member in an unextended configuration, wherein the cutting member is positioned adjacent the throughbore,
reconfiguring the cutting member in an extended configuration, wherein the cutting portion extends laterally beyond the body, and
rotating the tool.
According to an aspect of the invention there is provided a downhole tool cutting member, the cutting member comprising a cutting portion and a rear portion, the rear portion distal from the cutting portion in a direction of extension of the cutting member, wherein the cutting member is configured to position the rear portion rearwards of the center of a downhole tool in an unextended configuration.
According to an aspect of the invention there is provided a downhole tool cutting member, the cutting member comprising a cutting portion, a side portion and a rear portion, the rear portion distal from the cutting portion in a direction of extension of the cutting member and the side portion between the cutting portion and the rear portion, wherein the side portion is configured to receive a rear portion of a second cutting member in an unextended configuration in a downhole tool.
According to an aspect of the invention there is provided a downhole tool cutting member for mounting in a downhole tool, the cutting member configured to be mounted for extension along an axis offset from a central longitudinal axis of the downhole tool.
The axis may be offset from a radius perpendicular to the downhole tool central longitudinal axis. The axis may be parallel to the radius perpendicular to the downhole tool central longitudinal axis.
According to an aspect of the invention there is provided a downhole tool cutting member for mounting in a downhole tool, the cutting member configured to be mounted for extension along an axis offset from a radius the downhole tool.
According to an aspect of the invention there is provided a downhole tool actuation member, the actuation member configured to be operatively associated with an extendable cutting member and movable relative to a downhole tool body to extend the cutting member laterally from the body along an extension axis;
wherein the actuation member comprises a cutting member retention portion offset from a radius of the actuation member.
The cutting member retention portion may comprise a single cutting member retention element. Accordingly the actuation member may comprise a skewed retention portion. The actuation member may comprise a cutting member retention portion for multiple cutting members (e.g. three cutting members). The actuation member may comprise a single retention element for each cutting member, each retention element skewed about a longitudinal axis of the actuation member in a same direction (e.g. clockwise).
The invention includes one or more corresponding aspects, embodiments or features in isolation or in various combinations whether or not specifically stated (including claimed) in that combination or in isolation. For example, it will readily be appreciated that features recited as optional with respect to one aspect may be additionally applicable with respect to any of the other aspects, without the need to explicitly and unnecessarily list those various combinations and permutations here.
The above summary is intended to be merely exemplary and non-limiting.
These and other aspects of the present invention will now be described, by way of example only, with reference to the accompanying drawings, in which:
Reference is first made to
Reference is now made to
The underreamer 40 comprises an elongate tubular body 42, that can be formed from a number of connected parts. Windows 44 in the body 42 accommodate the extendable cutters 46 which co-operate with corresponding cam members 48 arranged about a central member 50 with a throughbore 52, whereby axial movement of the cam members 48 causes the respective cutters 46 to extend and retract along a central axis of extension 49.
The cutters 46 are mounted offset in the body 42. Accordingly, a projection of the central axis of extension 49 of a cutter 46 does not intersect the center 60 of the underreamer 40. The central axis of extension 49 is offset from a radius 61 of the underreamer 40, as defined by a radius of the body. In the retracted configuration of
The longer first side portion 51 of the cutter 46 enables the cross-sectional area 54 of
It will be apparent to those of skill in the art that the above described embodiment is merely exemplary of the present invention, and that various modifications and improvements may be made thereto, without departing from the scope of the invention. For example, although shown in here as an underreamer, it will be appreciated that features of the invention may be appropriately applicable to reamers or stabilizers or the like.
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1022040.8 | Dec 2010 | GB | national |
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PCT/GB2011/001778 | 12/29/2011 | WO | 00 | 9/13/2013 |
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