Embodiments described herein generally relate to monitoring the position of a downhole tool in a wellbore. More particularly, the embodiments relate to monitoring the position of a service tool during sand control operations.
Conventional sand control operations have included a service tool and a lower completion assembly. The service tool is coupled to the lower completion assembly, and the two components are run in hole together. Once they reach the desired depth, a packer coupled to the lower completion assembly is set to anchor the lower completion assembly in the wellbore. After the packer is set, the service tool is released from the lower completion assembly. Once released, the service tool can be used in the gravel packing process.
The gravel packing process requires moving the service tool within the wellbore to align one or more crossover ports in the service tool with one or more completion ports in or above the lower completion assembly. As such, aligning the ports requires precise positioning of the service tool. Downhole forces, however, such as pressure, drag on the drillpipe, and/or contraction and expansion of the drillpipe will generally affect the position of the service tool, making it difficult to align the ports. What is needed, therefore, is an improved system and method for monitoring the position of the service tool in the wellbore.
Systems and methods for monitoring the position of a service tool in a wellbore are provided. In one aspect, the method can be performed by positioning the service tool in the wellbore, and the service tool can have a sensor assembly coupled thereto. The service tool can be moved within the wellbore. The distance travelled by the service tool in the wellbore can be measured with the sensor assembly. The position of the service tool in the wellbore can be determined by comparing the distance travelled to a stationary reference point.
In one aspect, the system can include a completion assembly and a service tool. A packer can be coupled to the completion assembly and adapted to anchor the completion assembly in a stationary position within a wellbore. The service tool can be coupled to the completion assembly, and the service tool can be adapted to release from the completion assembly after the packer is anchored. A sensor assembly can be coupled to the service tool. The sensor assembly can include a wheel that is adapted to contact and roll along a wall of the wellbore as the service tool moves a distance within the wellbore. The sensor assembly can be adapted to measure the distance travelled by the service tool, and the distance can correspond to a number of revolutions of the wheel. The sensor assembly can be adapted to determine a position of the service tool in the wellbore by comparing the distance travelled to a stationary reference point.
So that the recited features can be understood in detail, a more particular description, briefly summarized above, can 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 illustrate only typical embodiments and are therefore not to be considered limiting of its scope, for the invention can admit to other equally effective embodiments.
The service tool 106 can include one or more tool position sensors or sensor assemblies (one is shown) 110 adapted to monitor the position of the service tool 106 in the wellbore 102. If the service tool 106 includes multiple sensor assemblies 110, the sensor assemblies 110 can be axially and/or circumferentially offset on the service tool 106. The sensor assembly 110 in
Once the packers 114 have been set, the sensor assembly 110 can actuate into the engaged position such that at least a portion of the sensor assembly 110, e.g., a wheel as described further below, is in contact with the wall 112 of the wellbore 102. The sensor assembly 110 can be in the engaged position when the service tool 106 is run into the wellbore 102, operated at depth in the wellbore 102, e.g., circulating and reversing, and/or pulled out of the wellbore 102. For example, the sensor assembly 110 can be in the disengaged position when the service tool 106 is run into the wellbore 102, and in the engaged position when the service tool 106 is operated at depth in the wellbore 102 and pulled out of the wellbore 102. In another embodiment, the sensor assembly 110 can be in the disengaged position when the service tool 106 is run into the wellbore 102, in the engaged position while the service tool 106 is operated at depth in the wellbore, and in the disengaged position when the service tool 106 is pulled out of the wellbore 102. The sensor assembly 110 can be actuated into the engaged position by an electric motor, a solenoid, an actuator (including electric, hydraulic, or electro-hydraulic), a timer-based actuator, a spring, pressure within the wellbore 102, or the like. Once in the engaged position, the sensor assembly 110 can maintain contact with the wall 112 of the wellbore 102 via a spring, a wedge, an actuator, a screw jack mechanism, or the like.
The sensor assembly 110 can activate and begin taking measurements to monitor the position of the service tool 106 in the wellbore 102 when the sensor assembly 110 actuates into the engaged position, i.e., contacts the wall 112, or the sensor assembly 110 can activate at a later, predetermined time. For example, the sensor assembly 110 can activate when a predetermined temperature or pressure is reached or when a signal (via cable or wirelessly) is received.
In at least one embodiment, once the sensor assembly 110 is activated, the service tool 106 can release from the lower completion assembly 108 such that that the service tool 106 is free to move axially and rotationally within the wellbore 102 with respect to the stationary lower completion assembly 108. The sensor assembly 110 can be adapted to take measurements to monitor the axial and/or rotational position of the service tool 106 as the service tool 106 is run in the wellbore 102, operated at depth in the wellbore 102, and/or pulled out of the wellbore 102.
Another embodiment of the sensor assembly 110 can also measure rotation of the service tool 106 with respect to the anchored lower completion assembly 108 or reference point 120 in the wellbore 102. In at least one embodiment, the service tool 106 can be released or disconnected from the anchored lower completion assembly 108 by rotating the service tool 106 to unthread it from the lower completion assembly 108. The sensor assembly 110 can be adapted to measure both axial and rotational movement of the service tool 106 with respect to the wellbore 102.
The position of the service tool 106 within the wellbore 102 can be measured with respect to a reference point 120 having a known position within the wellbore 102. For example, the reference point 120 can be located on the stationary lower completion assembly 108. In at least one embodiment, the service tool 106 can be pulled out of the wellbore 102 after it is released from the completion assembly 108, and a second service tool (not shown) can be run in the wellbore 102. The second service tool can also have a sensor assembly coupled thereto and use the reference point 120 on the lower completion assembly 108.
The measurements can be processed in the service tool 106 and/or transmitted to an operator and/or recording device at the surface through a wire or wirelessly. For example, the measurements can be transmitted via wired drill pipe, cable in the workstring 104, cable in the annulus 116, acoustic signals, electromagnetic signals, mud pulse telemetry, or the like. The measurements can be processed in the service tool 106 and/or transmitted to the surface continuously or intermittently to determine the position of the service tool 106 in the wellbore 102. In at least one embodiment, time between the processing and/or transmission of the measurements can be from about 0.5 s to about 2 s, about 2 s to about 10 s, about 10 s to about 30 s, about 30 s to about 60 s (1 min), about 1 min to about 5 min, about 5 min to about 10 min, about 10 min to about 30 min, or more.
The second axle 504 can be coupled to and extend through the wheel 510 proximate a second end 516 of the yoke 508. When in the engaged position, the wheel 510 can be adapted to roll against the wellbore 102, i.e., roll along the wall 112 of the wellbore 102, as the service tool 106 moves within the wellbore 102 (see
In at least one embodiment, one or more magnets (one is shown) 518 can be disposed on or in the second axle 504 and/or the wheel 510 such that the magnet 518 is adapted to rotate through the same angular distance as the wheel 510. As the magnet 504 rotates, the magnetic field produced by the magnet 504 can vary. The sensor 512 can be disposed proximate the magnet 504 and adapted to sense or measure the variations in the magnetic field as the magnet 504 rotates. In at least one embodiment, the sensor 512 can be disposed in an atmospheric chamber 520. As such, a wall 522 can be disposed between the magnet 518 and the sensor 512. The atmospheric chamber 520 can be airtight to prevent fluid from the wellbore 102 from leaking therein.
One or more circuits (one is shown) 524 can also be disposed within the atmospheric chamber 520 and in communication with the sensor 512; however, in at least one embodiment, the sensor 512 and the circuit 524 can be a single component. The circuit 524 can be adapted to receive the measurements from the sensor 512 corresponding to the variations in the magnetic field and determine the number of revolutions and/or partial revolutions completed by the wheel 510. The circuit 524 can then measure the distance travelled by the service tool 106 in the wellbore 102 (see
The number of revolutions completed by the wheel 510 and/or the distance travelled by the service tool 106 can be transmitted to an operator or recording device at the surface through a wire or wirelessly. For example, a cable or wire (not shown) may be adapted to receive signals from the sensor 512 and/or circuit 524 through a bulkhead 526. The cable can run through a channel 528 in the yoke 508 and out an opening 530 through the end 514 of the yoke 508. In at least one embodiment, the yoke 508 can be made of a non-magnetic material. For example, the yoke 508 can be made of a metallic alloy, such as one or more INCONEL® alloys.
D=2*Π*R
where D is the distance, and Π is the mathematical constant pi, and R is the radius of the wheel 700. The velocity of the service tool 106 in the wellbore 102 can also be calculated the following equation:
V=D/t
where V is the velocity, D is the distance, and t is time. The acceleration can also be calculated by the following equation:
A=V/t
where A is the acceleration, V is the velocity, and t is time.
The radius R of the wheel 700 is a known quantity and can range from a low of about 0.05 cm, about 1 cm, about 2 cm, or about 3 cm to a high of about 5 cm, about 10 cm, about 20 cm, about 40 cm, or more. For example, the radius R of the wheel 700 can be from about 1 cm to about 3 cm, about 3 cm to about 6, about 6 cm to about 10 cm, or about 10 cm to about 20 cm.
One or more targets (six are shown) 702a-f can be disposed at different circumferential positions on the wheel 700. As the number of targets 706a-f increases, the precision of the measurement of the distance D can also increase. The distance D travelled by the service tool 106 can be calculated the following equation:
D=(2*Π*R*S)/N
where S is the number of targets 702a-f sensed or counted by the sensor, e.g., sensor 800 in
The targets 702a-f can be disposed on the side or axial end 704 of the wheel 700, as shown, or the targets 702a-f can be disposed on the radial end 706 of the wheel 700. For example, the targets 702a-f can be disposed within one or more recesses (not shown) on the radial end 706 of the wheel 700 so that the targets 702a-f do not come in direct contact with the wall 112 of the wellbore 102 (see
The communication between the targets 702a-f and the sensor 800 can be magnetic, mechanical, optical, or direct contact. For example, the targets 702a-f can be magnets, as described above. In another embodiment, the targets 702a-f can be radio frequency identification (RFID) tags. The distance between the sensor 800 and the targets 702a-f can range from a low of about 0 cm (direct contact), about 0.1 cm, about 0.2 cm, or about 0.3 cm to a high of about 0.5 cm, about 1 cm, about 5 cm, about 10 cm, or more. For example, the distance between the sensor 800 and the targets 702a-f can be from about 0 cm to about 0.2 cm, about 0.2 cm to about 0.5 cm, about 0.5 cm to about 1 cm, or about 1 cm to about 4 cm.
The gear 1006 can be coupled to the shaft 1004 and adapted to rotate through the same angular distance as the shaft 1004. The gear 1006 can include one or more teeth 1014 disposed on an outer radial or axial surface thereof. The number of teeth 1014 can range from a low of about 1, about 2, about 4, about 5, or about 6 to a high of about 8, about 10, about 12, about 20, about 24, or more. For example, the number of teeth 1014 can range from about 1 to about 4, from about 4 to about 8, from about 8 to about 12, or from about 12 to about 24.
The sensor 1008 can be in direct or indirect contact with the gear 1006 and adapted to sense or count the number of teeth 1014 that pass by as the gear 1006 rotates. This measurement can be used to calculate the distance D that the service tool 106 moves in the wellbore 102. This measurement can also be used to calculate the velocity V and/or the acceleration A of the service tool 106 in the wellbore 102. In at least one embodiment, the gear 106 can be in direct contact with the wall 112 of the wellbore 102, and the sensor 1008 can be exposed, i.e., not disposed within the housing 1010.
At least one of (1) the distance travelled by the service tool 106 and (2) the position of the service tool 106 can be transmitted to an operator or recording device at the surface. Once the distance travelled by the service tool 106 and/or position of the service tool 106 are known, the operator or recording device can move the service tool 106 to precise locations within the wellbore 102. For example, the service tool 106 can be moved to the first, circulating position to align one or more one or more crossover ports 130 (see
The distance that the service tool 106 needs to travel, e.g., the distance between the ports 130, 132 when the service tool 106 is released from the lower completion assembly 108, can be a known quantity. The sensor assembly 110 can then measure the distance that the service tool 106 travels, to facilitate alignment of the ports 130, 132. For example, the distance between the crossover port 130 and the completion port 132 can be 1 m when the service tool 106 is released from the lower completion assembly 108. If the radius R (also a known quantity) of the wheel 308, 510, 700, 902, 1002 in the sensor assembly 110 is 10 cm (0.1 m), a single revolution of the wheel 308, 510, 700, 902, 1002 represents a distance D travelled calculated by the following equation:
D=2*Π*R=2*Π*0.1=0.628 m
The number of revolutions that the wheel 308, 510, 700, 902, 1002 will have to complete to move the service tool 1 m can be calculated by the following equation:
(0.628 m)/(1 revolution)=(1 m)/(X revolutions)
In this exemplary embodiment, X equals about 1.6 revolutions, and thus, when the wheel 308, 510, 700, 902, 1002 completes about 1.6 revolutions, the service tool 106 will have moved 1 m, and the ports 130, 132 will be aligned.
Once the ports 130, 132 are aligned, the lower annulus 118 can be gravel packed. A treatment fluid, such as a gravel slurry including a mixture of a carrier fluid and gravel, can flow through the service tool 106, through the ports 130, 132, and into the lower annulus 118 between one or more screens 134 in the lower completion assembly 108 and the wall 112 of the wellbore 102. A carrier fluid of the gravel slurry can flow back into the service tool 106 leaving the gravel disposed in the annulus 118. The gravel forms a permeable mass or “pack” between the one or more screens 134 and the wall 112 of the wellbore 102. The gravel pack allows production fluids to flow therethrough while substantially blocking the flow of any particulate material, e.g., sand.
At certain times during use of the service tool 106, the service tool 106 can move axially within the wellbore 102 due to various forces acting on it. The forces can include pressure, drag on the workstring 104, and contraction and expansion of the workstring 104 due to temperature changes. For example, during the circulation process, the net pressure forces on the service tool 106 can push the service tool 106 upward in the wellbore 102. This upward movement of the service tool 106 can be compounded by the contraction of the workstring 104 as it cools during pumping. The sensor assembly 110 can be used to determine the position of the service tool 106 in the wellbore 102 both axially and rotationally, and in response to the determined position, additional weight and/or rotation can be added or removed at the surface to maintain the service tool 106 in the desired position, e.g., with the ports 130, 132 aligned. The monitoring of the position of the service tool 106 and corresponding variation of weight at the surface can be used for other operations as well, including when the service tool 106 is in the secondary release, squeeze, dump seal, or reversing positions.
(0.628 m)/(1 revolution)=(2.5 m)/(X revolutions)
where X is the number of revolutions of the wheel. For example, when X equals about 4 revolutions, and thus, when the wheel 308, 510, 700, 902, 1002 completes about 4 revolutions, the service tool 106 will have moved 2.5 m, and the crossover port 130 will be in the desired positioned above the packers 114.
Once in the reversing position, pressure can be applied to the upper annulus 116 to reverse the remaining gravel slurry in the service tool 106 back to the surface. The high pressure in the upper annulus 116 can force a wellbore fluid in the annulus 116 through the port 130, thereby forcing the gravel slurry in the service tool 106 to the surface. With the position of the service tool 106 known, the pumping can begin as soon as the service tool 106 enters the reversing position and before annular pressure bleeds off completely.
The sensor assembly 1300 can include an arm or yoke 1310 having a wheel 1312 coupled thereto. The yoke 1310 and wheel 1312 can be substantially similar to the yoke 508 and wheel 510 described above, and thus will not be described again in detail. One or more electronic components 1314 can be disposed within the housing 1301. The electronic components 1314 can include one or more circuits adapted to receive the data from the wheel 1312, e.g., the number of revolutions. In at least one embodiment, the electronic components 1314 can be adapted to measure the distance travelled by the service tool 106 based on the data from the wheel 1312. In another embodiment, the electronic components 1314 can be adapted to measure the distance travelled by the service tool 106 and determine the position of the service tool 106 in the wellbore 102 based upon the distance measurements. As described above, the electronic components can be adapted to transmit the distance travelled and/or the position of the service tool 106 in the wellbore to an operator or recording device at the surface.
One or more batteries 1316 can also be disposed within the housing 1301. For example, the batteries 1316 can form an annular battery pack within the housing 1301. The batteries 1316 can be adapted to supply power to the yoke 1310, the motor actuating the yoke 1310, the electronic components 1314, or other downhole devices.
Referring again to
The sensor assembly 110 described herein can be used by any downhole tool to measure downhole distances and determine downhole positions. For example, the sensor assembly 110 can be used in a centralizer used in other wireline tools, drilling and measurement logging tools, shifting tools, and fishing tools that are used to, for example, create logs of information about the adjacent formation or map the adjacent formation. As such, the position of the downhole tool can be correlated with logs, maps, or the like.
Alternative technologies for measuring and monitoring the position of the service tool 106 in the wellbore 102 can include acoustic, magnetic, and electromagnetic techniques. The position of the service tool 106 can also be measured and monitored with a linear variable differential transformer or a tether or cable coupled to the service tool 106. For example, one end of a tether can be coupled to the service tool 106, and the other end of the tether can be coupled to the stationary lower completion assembly 108 or packers 114. The tether can be in tension as the service tool 106 moves within the wellbore 102. Thus, as the service tool 106 moves with respect to the stationary lower completion assembly 108 or packers 114, the length of the tether can vary. The length of the tether can be measured to determine the position of the service tool 106 in the wellbore 102. Upon completion of the job, the tether can be released or severed from the lower completion assembly 108 or packers 114 allowing the service tool 106 to be pulled out of the wellbore 102.
In another embodiment, the sensor assembly 110 can include an acoustic sensor or transceiver, and the reference point 120 can include a target. The target 120 can be placed on the stationary lower completion assembly 108 or the packers 114. The sensor assembly 110 can be adapted to send acoustic signals to and receive acoustic signals from the target 120. The signals can be used to determine a distance travelled by the service tool 106 and/or the position of the service tool 106 in the wellbore 102. At least one of the distance travelled and the position of the service tool 106 can then be transmitted to an operator or recorder at the surface, and once the position is known or determined (based on the distance travelled), the service tool 106 can be moved to precise locations within the wellbore 102.
Various terms have been defined above. To the extent a term used in a claim is not defined above, it should be given the broadest definition persons in the pertinent art have given that term as reflected in at least one printed publication or issued patent. Furthermore, all patents, test procedures, and other documents cited in this application are fully incorporated by reference to the extent such disclosure is not inconsistent with this application and for all jurisdictions in which such incorporation is permitted.
While the foregoing is directed to embodiments of the present invention, other and further embodiments of the invention can be devised without departing from the basic scope thereof, and the scope thereof is determined by the claims that follow.
This application claims the benefit of and priority to U.S. provisional patent application having Ser. No. 61/435,186 that was filed on Jan. 21, 2011 and is a continuation of U.S. patent application Ser. No. 13/355,067 filed Jan. 20, 2012, both of which are hereby incorporated by reference herein in their entirety.
Number | Date | Country | |
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61435186 | Jan 2011 | US |
Number | Date | Country | |
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Parent | 13355067 | Jan 2012 | US |
Child | 14875608 | US |