Embodiments described herein generally relate to downhole tools. More particularly, such embodiments relate to underreamers and expandable stabilizers for enlarging the diameter of a wellbore.
After a wellbore is drilled, an underreamer is oftentimes used to enlarge the diameter of the wellbore. The underreamer is run into the wellbore in an inactive state. In the inactive state, cutter blocks on the underreamer are folded inwardly toward the body of the underreamer such that the cutter blocks are positioned radially-inward from the surrounding casing or wellbore wall. Once the underreamer reaches the desired depth in the wellbore, the underreamer is actuated in to an active state. In the active state, the cutter blocks move radially-outward and into contact with the wellbore wall. The cutter blocks are then used to increase the diameter of the wellbore.
Conventional underreamers have cutter blocks with a fixed outer diameter when in the active state. As such, conventional underreamers are adapted to create a segment of the wellbore having an increased, but uniform, diameter. It is oftentimes desirable, however, for the wellbore to have varying diameters. For example, cutter blocks become worn down due to excessive vibration in the wellbore. Reducing the diameter of the cutter blocks tends to stabilize the downhole tool, thereby reducing or eliminating wear on the cutter blocks. Currently, this is achieved by pulling the underreamer out of the wellbore to the surface to adjust the outer diameter of the cutting blocks. This delay can lead to lost profits in the field.
This summary is provided to introduce a selection of concepts that are further described below in the detailed description. This summary is not intended to identify key or essential features of the claimed subject matter, nor is it intended to be used as an aid in limiting the scope of the claimed subject matter.
An underreamer for increasing a diameter of a wellbore is disclosed. The underreamer includes a body having an axial bore extending at least partially therethrough. An annular sleeve is coupled to the body and adapted to move with respect to the body. The sleeve may include a plurality of grooves formed therein that are circumferentially offset from one another. A pin may be coupled to the body. The sleeve is adapted to move with respect to the pin to transition the pin from a first groove in the sleeve to a second groove in the sleeve. The sleeve is in a first axial position with respect to the body when the pin is positioned in the first groove, and the sleeve is in a second axial position with respect to the body when the pin is positioned in the second groove. A cutter block is coupled to the body. The cutter block moves from a first outer diameter when the sleeve is in the first axial position to a second outer diameter when the sleeve is in the second axial position.
A method for increasing a diameter of a wellbore is also disclosed. The method may include moving an annular sleeve within a body to transition a pin coupled to the body from a first groove in the sleeve to a second groove in the sleeve. The sleeve is in a first axial position with respect to the body when the pin is positioned in the first groove, and the sleeve is in a second axial position with respect to the body when the pin is positioned in the second groove. A cutter block coupled to the body moves from a first outer diameter when the sleeve is in the first axial position to a second outer diameter when the sleeve is in the second axial position. The cutter block increases the diameter of the wellbore.
Another embodiment of an underreamer is further disclosed. The underreamer includes a body having an axial bore extending at least partially therethrough. A cutter block is coupled to the body and adapted to increase the diameter of the wellbore. A linear actuator is coupled to the body. An axial position of the cutter block is determined by a position of the linear actuator, and the cutter block is adapted to move radially outward as the cutter block moves axially.
So that the recited features may be understood in detail, a more particular description, briefly summarized above, may be had by reference to one or more embodiments, some of which are illustrated in the appended drawings. It is to be noted, however, that the appended drawings are illustrative embodiments, and are, therefore, not to be considered limiting of its scope.
A ball seat 110 may be disposed within the bore 108. The ball seat 110 may be formed by a transition from a larger inner diameter of the bore 108 to a smaller inner diameter of the bore 108. The ball seat 110 is adapted to receive an impediment, such as a ball 112, that enters the bore 108 through the first end portion 104 thereof. The ball 112 forms a fluid tight seal against the ball seat 110 when fluid pressure is applied to the bore 108 via the first end portion 104 of the bore 108. The ball seat 110, the ball 112, or both may be deformable when exposed to a predetermined fluid pressure in the bore 108. An illustrative ball seat 110 is shown and described in U.S. Pat. No. 7,681,650, the content of which is incorporated by reference to the extent consistent with the present disclosure.
An annular sleeve 200 is disposed within the body 102 and coupled to the ball seat 110. When the ball 112 is received in the ball seat 110, fluid pressure may be applied to the bore 108 from the surface (e.g., via mud pumps). The fluid pressure causes the ball seat 110 and the sleeve 200 to move or stroke in a first axial direction within the body 102, e.g., toward the second end portion 106 of the body 102. Movement of the sleeve 200 in the first axial direction may compress a spring 114. When a predetermined fluid pressure is reached, at least one of the ball seat 110 and the ball 112 may deform to allow the ball 112 to pass through the ball seat 110. When the ball 112 passes through the ball seat 110, the compressed spring 114 causes the ball seat 110 and the sleeve 200 to move or stroke in a second axial direction within the body 102, e.g., toward the first end portion 104 of the body 102. Although
Although three grooves 220, 230, 240 as shown in
Referring now to
The force applied by the spring 114 causes the pin 116 to be positioned proximate the end portion 222, 232, 242 of the groove 220, 230, 240 after each stroke is complete. In addition, the force applied by one or more cutter blocks also causes the pin 116 to be positioned proximate the end portion 222, 232, 242 of the groove 220, 230, 240 after each stroke is complete, as discussed in more detail below.
The position of the pin 116 in the indexing mechanism 210 determines the axial position of the sleeve 200 with respect to the body 102 of the underreamer 100. For example, as the pin 116 transitions from the end portion 222 of the first groove 220 to the end portion 232 of the second groove 232, the sleeve 200 slides axially toward the first end portion 104 of the body 100 because the second groove 230 is longer than the first groove 220. Similarly, when the pin 116 moves from the end portion 232 of the second groove 230 to the end portion 242 of the third groove 240, the sleeve 200 slides further toward the first end portion 104 of the body 102 because the third groove 240 is longer than the second groove 230. In at least one embodiment, the order and/or length of the grooves 220, 230, 240 may be varied such that the sleeve 200 slides toward the first end portion 104 of the body 102 and/or toward the second end portion 106 of the body 102 by differing distances.
One or more cutter blocks (one is shown 120) is movably coupled to the body 102 of the underreamer 100. Although a single cutter block 120 may be seen in
The cutter block 120 shown in
The cutter block 120 has a plurality of splines 131 disposed or formed on the outer side surfaces thereof. The splines 131 on the cutter block 120 may be or include offset ridges or protrusions adapted to engage and slide within corresponding grooves 133 in the body 102 of the underreamer 100. The splines 131 on the cutter block 120 are oriented at an angle with respect to the longitudinal axis through the body 102 of the underreamer 100. The angle of the splines 131 on the cutter block 120 (and the corresponding grooves 133 in the body 102) may range from a low of about 10°, about 15°, about 20°, or about 25° to a high of about 30°, about 40°, about 50°, about 60°, or more. For example, the angle may be between about 15° and about 25° with respect to the longitudinal axis through the body 102.
When an axial force is exerted on the cutter block 120 in a direction toward the first end portion 104 of the body 102, the engagement of the splines 131 on the cutter block 120 and the grooves 133 in the body 102 causes the cutter block 120 to simultaneously move axially toward the first end portion 104 of the body 102 and radially outward (e.g., between about 15° and about 25° with respect to the longitudinal axis through the body 102). This movement transitions the cutter block 120 from the inactive state (e.g., first diameter 132) to the active state (e.g., second diameter 134 or third diameter 136).
Axial movement of the cutter block 120, however, is limited by the position of the sleeve 200. In other words, when the cutter block 120 contacts the sleeve 200, it is prevented from moving further toward the first end portion 104 of the body 102. When axial movement toward the first end portion 104 of the body 102 is prevented, movement radially outward is also prevented. As such, the outer diameter of the cutter block 120 is determined by the position of the sleeve 200 and, as discussed above, the position of the sleeve 200 is determined by the position of the pin 116 in the indexing mechanism 210.
In operation, the underreamer 100 is run into the wellbore 150 with the cutter block 120 at the first diameter 132 (i.e., in the inactive state), as shown in
The sleeve 200 is held in place by the interaction between the pin 116 and the indexing mechanism 210. For example, when the pin 116 is positioned proximate the end portion 222 of the first or “shortest” groove 220, the sleeve 200 is secured in a position that maintains the cutter block 120 at the first diameter 132.
To actuate or adjust the cutter block 120 of the underreamer 100 from the first diameter 132, as shown in
As discussed above, movement of the sleeve 200 in an axial direction (i.e., toward the first end portion 104 and/or the second end portion 106 of the body 102) also causes the sleeve 200 to rotate about a longitudinal axis extending therethrough. The axial and rotational movement of the sleeve 200 causes the pin 116 to transition from the end portion 222 of the first groove 220 to the end portion 232 of the second groove 230. When the pin 116 transitions to the end portion 232 of the second groove 230, the sleeve 200 slides axially toward the first end portion 104 of the body 102 a distance 250 due to the increased length of the second groove 230.
Fluid pressure is then applied to the bore 108 from the surface. The fluid pressure in the bore 108 causes a chamber 124 disposed between the cutter block 120 and the second end portion 106 of the body 102 to become pressurized (e.g., by opening a port or valve therebetween). The pressurized chamber 124 exerts a force on the cutter block 120 in a direction toward the first end portion 104 of the body 102. As the sleeve 200 has moved axially toward the first end portion 104 of the body 102 a distance 250, the cutter block 120 may move axially toward the first end portion 104 of the body 102 a distance 250 until it once again contacts the sleeve 200 (or stop ring 122 coupled thereto) preventing further axial movement. The cutter block 120 moves radially outward to the second diameter 134 simultaneously with its movement toward the first end portion 104 of the body 102. When the axial movement is restricted by the sleeve 200, the radial movement is restricted as well, and the cutter block 120 is set at the second diameter 134, as shown in
Fluid pressure may continue to be applied to the chamber 124 via the bore 108 to maintain the cutter block 120 at the second diameter 134. When the cutter block 120 is at the second diameter 134, it is in the active state and may cut or grind the wall 152 of the wellbore 150 to increase the diameter of a portion of the wellbore 150 to the second diameter 134.
To actuate or adjust the cutter block 120 of the underreamer 100 from the second diameter 134, as shown in
The axial and rotational movement of the sleeve 200 causes the indexing mechanism 210 to move with respect to the pin 116 such that the pin 116 transitions from the end portion 232 of the second groove 230 to the end portion 242 of the third groove 240. When the pin 116 transitions to the end portion 242 of the third groove 240, the sleeve 200 slides axially toward the first end portion 104 of the body 102 a distance 252 due to the increased length of the third groove 240. The distance 252 may be the same or different than the distance 250.
Fluid pressure is then applied to the bore 108 from the surface. The fluid pressure in the bore 108 causes the chamber 124 to become pressurized. The pressurized chamber 124 exerts a force on the cutter block 120 toward the first end portion 104 of the body 102. As the sleeve 200 has moved axially toward the first end portion 104 of the body 102 a distance 252, the cutter block 120 moves axially toward the first end portion 104 of the body 102 a distance 252 until it once again contacts the sleeve 200 (or stop ring 122 coupled thereto) preventing further axial movement. The cutter block 120 moves radially outward to the third diameter 136 simultaneously with its movement toward the first end portion 104 of the body 102. When the axial movement is restricted by sleeve 200, the radial movement is restricted as well, and the cutter block 120 is set at the third diameter 136, as shown in
Fluid pressure may continue to be applied to the chamber 124 via the bore 108 to maintain the cutter block 120 at the third diameter 136. When the cutter block 120 is at the third diameter 136, the cutter block 120 is in the active state and may cut or grind the wall 152 of the wellbore 150 to increase the diameter of a portion of the wellbore 150 to the third diameter 136.
To actuate or adjust the cutter block 120 of the underreamer 100 from the third diameter 136, as shown in
The axial and rotational movement of the sleeve 200 causes the indexing mechanism 210 to move with respect to the pin 116 such that the pin 116 transitions from the end portion 242 of the third groove 240 to the end portion of a fourth groove (not shown). The fourth groove may have a length similar to the first groove 220, the second groove 230, or any other length. When the pin 116 transitions to the end portion of the fourth groove, the sleeve 200 slides axially toward the second end portion 106 of the body 102 a distance 252 (if the fourth groove has a length similar to the second groove 230) or a distance 250+252 (if the fourth groove has a length similar to the first groove 220). When the sleeve 200 slides axially toward the second end portion 106 of the body 102, the sleeve 200 moves the cutter block 120 toward the second end portion 106 of the body 102 a distance 252 (or a distance 250+252). If the cutter block 120 moves toward the second end portion 106 of the body a distance 252, the cutter block 120 simultaneously moves from the third diameter 136 to the second diameter 134. If the cutter block 120 moves toward the second end portion 106 of the body a distance 250+252, the cutter block 120 simultaneously moves from the third diameter 136 to the first diameter 132.
Fluid pressure is then applied to the bore 108 from the surface. The fluid pressure in the bore 108 causes the chamber 124 to become pressurized. The pressurized chamber 124 exerts a force on the cutter block 120 toward the first end portion 104 of the body 102. The fluid pressure may maintain the cutter block 120 at the second diameter 134, or any other diameter depending on the length of the fourth groove.
Therefore, the cutting diameter 132, 134, 136 of the cutter block 120 may be varied while the underreamer 100 is disposed within the wellbore 150. In at least one embodiment, the cutter block 120 may increase the diameter of a first portion of the wellbore 150 to the second diameter 134 and increase the diameter of a second portion of the wellbore 150 to the third diameter 136. In another embodiment, the cutter block 120 may first increase the diameter of a portion of the wellbore 150 to the second diameter 134 and then increase the diameter of the same portion of the wellbore 150 to the third diameter 136.
The linear actuator 510 is adapted to move the sleeve 200 axially to limit the axial and radial movement of the cutter block 120, thereby determining the outer diameter 530 of the cutter block 120 in the same manner as described above. The linear actuator 510 moves the sleeve 200 between two or more predetermined axial positions, and each axial position of the sleeve 200 enables the cutter block 120 to have a different outer diameter 530.
The position (i.e., relative actuation) of the linear actuator 510 indicates and/or signals the axial position of the cutter block 120. As disclosed above, the cutter block 120 moves relative to the body 102 via splines 131 and corresponding grooves 133 in the body 102; therefore, the radial extension of the cutter block 120 relative to the body 102 can then be determined once the axial position of the cutter block is known.
The linear actuator 510 has a control unit 520 coupled thereto or integral therewith. The control unit 520 is adapted to control the movement of the sleeve 200 by the linear actuator 510 in response to a signal received from the surface. The signal may be or include a mud pulse signal, an electromagnetic signal, an electric signal, a hard wire (e.g., intelliserv) magnetic signal, an acoustic signal, a pressure signal, or the like. The linear actuator 510 may also have a power source, e.g., a battery, coupled thereto to power its operation. Such power source may also couple to and power the control unit 520.
Rather than restricting or limiting the movement of the cutter block 120, however, the linear actuator 610 may be adapted to move or push the cutter block 120 toward the first end portion 104 of the body 102, thereby increasing the diameter 630 of the cutter block 120. For example, the linear actuator 610 may move the cutter block 120 between two or more predetermined axial positions, and each axial position of the cutter block 120 may correspond to a different outer diameter 630. In at least one embodiment, a drive ring 640 is disposed between the linear actuator 610 and the cutter block 120 to transmit the force from the linear actuator 610 to the cutter block 120, or vice versa.
The position (i.e., relative actuation) of the linear actuator 610 indicates and/or signals the axial position of the cutter block 120. As disclosed above, the cutter block 120 moves relative to the body 102 via splines 131 and corresponding grooves 133 in the body 102; therefore, the radial extension of the cutter block 120 relative to the body 102 can then be determined once the axial position of the cutter block is known.
The linear actuator 610 has a control unit 620 coupled thereto or integral therewith. The control unit 620 is adapted to control the movement of the linear actuator 610 in response to a signal received from the surface. The signal may be or include a mud pulse signal, an electromagnetic signal, an electric signal, a hard wire (e.g., intelliserv) magnetic signal, an acoustic signal, a pressure signal, or the like. The linear actuator 610 may also have a power source, e.g., a battery, coupled thereto to power its operation. Such power source may also couple to and power the control unit 620.
As used herein, the terms “inner” and “outer”; “up” and “down”; “upper” and “lower”; “upward” and “downward”; “above” and “below”; “inward” and “outward”; and other like terms as used herein refer to relative positions to one another and are not intended to denote a particular direction or spatial orientation. The terms “couple,” “coupled,” “connect,” “connection,” “connected,” “in connection with,” and “connecting” refer to “in direct connection with” or “in connection with via one or more intermediate elements or members.”
Although only a few example embodiments have been described in detail above, those skilled in the art will readily appreciate that many modifications are possible in the example embodiments without materially departing from “Adjustable Diameter Underreamer and Methods of Use.” Accordingly, all such modifications are intended to be included within the scope of this disclosure. In the claims, means-plus-function clauses are intended to cover the structures described herein as performing the recited function and not only structural equivalents, but also equivalent structures. Thus, although a nail and a screw may not be structural equivalents in that a nail employs a cylindrical surface to secure wooden parts together, whereas a screw employs a helical surface, in the environment of fastening wooden parts, a nail and a screw may be equivalent structures. It is the express intention of the applicant not to invoke 35 U.S.C. §112, paragraph 6 for any limitations of any of the claims herein, except for those in which the claim expressly uses the words ‘means for’ together with an associated function.
This application claims the benefit of a related U.S. Provisional Application having Ser. No. 61/725,830 filed Nov. 13, 2012, entitled “Adjustable Diameter Underreamer and Methods of Use,” to Manoj Mahajan et al., the disclosure of which is incorporated by reference herein in its entirety.
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61725830 | Nov 2012 | US |