Disclosed embodiments relate generally to methods for maintaining directional control during downhole directional drilling operations and more particularly to method for determining a downhole toolface offset while drilling.
The use of automated drilling methods is becoming increasingly common in drilling subterranean wellbores. Such methods may be employed, for example, to control the direction of drilling based on various downhole feedback measurements, such as inclination and azimuth measurements made while drilling or logging while drilling measurements.
One difficulty with automated drilling methods (and directional drilling methods in general) is that directional drilling tools exhibit tendencies to drill (or turn) in a direction offset from the set point direction. For example, when set to drill a horizontal well straight ahead, certain drilling tools may have a tendency to drop inclination (turn downward) and/or to turn to the left or right. Exacerbating this difficulty, these tendencies can be influenced by numerous factors and may change unexpectedly during a drilling operation. Factors influencing the directional tendency may include, for example, properties of the subterranean formation, the configuration of the bottom hole assembly (BHA), bit wear, bit/stabilizer walk, an unplanned touch point (e.g. due to compression and buckling of the BHA), stabilizer-formation interaction, the steering mechanism utilized by the steering tool, and various drilling parameters.
In current drilling operations, a drilling operator generally corrects the directional tendencies by evaluating wellbore survey data transmitted to the surface. A surface computation of the gravity toolface of the well is generally performed at 30 to 100 foot intervals (e.g., at the static survey stations). While such techniques are serviceable, there is a need for further improvement, particularly for automatically accommodating (or correcting) such tendencies downhole while drilling.
A downhole closed loop method for controlling a drilling toolface of a subterranean borehole is disclosed. The method includes receiving reference and measured attitudes of the subterranean borehole while drilling with the reference attitude being measured at an upper survey station and the measured attitude being measured at a lower survey station. The reference attitude and the measured attitude are processed downhole while drilling (using a downhole processor) to compute an angle change of the subterranean borehole between the upper and lower survey stations. The computed angle change is compared with a predetermined threshold. This process may be continuously repeated while the angle change is less than the threshold. The reference attitude and the measured attitude are further processed downhole to compute a toolface angle when the angle change of the subterranean borehole is greater than or equal to the threshold. The toolface angle may then be further processed to control a direction of drilling of the subterranean borehole.
The disclosed embodiments may provide various technical advantages. For example, the disclosed embodiments provide for real-time closed loop control of the drilling toolface. As such, the disclosed methods may provide for improved well placement and reduced wellbore tortuosity. Moreover, by providing for closed loop control, the disclosed methods tend to improve drilling efficiency and consistency.
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.
For a more complete understanding of the disclosed subject matter, and advantages thereof, reference is now made to the following descriptions taken in conjunction with the accompanying drawings, in which:
It will be understood that the BHA may include substantially any suitable steering tool 60, for example, including a rotary steerable tool. Various rotary steerable tool configurations are known in the art including various steering mechanisms for controlling the direction of drilling. For example, many existing rotary steerable tools include a substantially non-rotating outer housing employing blades that engage the borehole wall. Engagement of the blades with the borehole wall is intended to eccenter the tool body, thereby pointing or pushing the drill bit in a desired direction while drilling. A rotating shaft deployed in the outer housing transfers rotary power and axial weight-on-bit to the drill bit during drilling. Accelerometer and magnetometer sets may be deployed in the outer housing and therefore are non-rotating or rotate slowly with respect to the borehole wall.
The POWERDRIVE® rotary steerable systems (available from Schlumberger) fully rotate with the drill string (i.e., the outer housing rotates with the drill string). The POWERDRIVE® XCEED™ makes use of an internal steering mechanism that does not require contact with the borehole wall and enables the tool body to fully rotate with the drill string. The POWERDRIVE® X5, X6, and POWERDRIVE ORBIT® rotary steerable systems make use of mud actuated blades (or pads) that contact the borehole wall. The extension of the blades (or pads) is rapidly and continually adjusted as the system rotates in the borehole. The POWERDRIVE ARCHER® makes use of a lower steering section joined at an articulated swivel with an upper section. The swivel is actively tilted via pistons so as to change the angle of the lower section with respect to the upper section and maintain a desired drilling direction as the bottom hole assembly rotates in the borehole. Accelerometer and magnetometer sets may rotate with the drill string or may alternatively be deployed in an internal roll-stabilized housing such that they remain substantially stationary (in a bias phase) or rotate slowly with respect to the borehole (in a neutral phase). To drill a desired curvature, the bias phase and neutral phase are alternated during drilling at a predetermined ratio (referred to as the steering ratio). Again, the disclosed embodiments are not limited to use with any particular steering tool configuration.
The downhole sensors 70 may include substantially any suitable sensor arrangement used making downhole navigation measurements (borehole inclination, borehole azimuth, and/or tool face measurements). Such sensors may include, for example, accelerometers, magnetometers, gyroscopes, and the like. Such sensor arrangements are well known in the art and are therefore not described in further detail. The disclosed embodiments are not limited to the use of any particular sensor embodiments or configurations. Methods for making real-time while drilling measurements of the borehole inclination and borehole azimuth are disclosed, for example, in commonly assigned U.S. Patent Publications 2013/0151157 and 2013/0151158. In the depicted embodiment, the sensors 70 are shown to be deployed in the steering tool 60. Such a depiction is merely for convenience as the sensors 70 may be deployed elsewhere in the BHA.
It will be understood by those of ordinary skill in the art that the deployment illustrated on
It will be understood that the disclosed embodiments are not limited to the above described conventions for defining borehole coordinates depicted in
At 108 the reference and measured attitudes are processed to compute an overall angle change β of the borehole between first and second survey stations (see
The attitude received at 106 may be measured, for example, using static and/or continuous inclination and azimuth measurement techniques. Static measurements may be obtained, for example, when drilling is temporarily suspended to add a new pipe stand to the drill string. Continuous measurements may be obtained, for example, from corresponding continuous measurements of the axial component of the gravitational and magnetic fields (Az and Bz in
The reference and measured attitudes may be processed at 108 to compute the angle β between the upper and lower survey stations, for example, as follows:
β=arccos{cos(Inclow−Incup)−sin(Inclow)sin(Incup)[1−cos(Azilow−Aziup)]} (1)
where Inclow and Azilow represent the measured attitude (inclination and azimuth) and Incup and Aziup represent the reference attitude (inclination and azimuth). Given that the overall angle change of the well is often small in a continuous drilling operation, one or more of the following approximations may be used when β is small (e.g., less than about 5 degrees):
When making continuous (while drilling) attitude measurements, the continuous azimuth measurements are commonly noisier than the continuous inclination measurements. As such, Equations 2-4 may be modified to include a weighting factor AW to desensitize the effect of the noisier azimuth on the overall angle change β.
wherein the weighting factor AW is in a range from 0 to 1 and may be selected based on the noise levels in the inclination and azimuth values. In certain embodiments, the weighting factor AW may be in a range from about 0.1 to about 0.5 (although the disclosed embodiments are by no means limited in this regard). Equations 2-7 may be advantageously utilized on a downhole computer/processor as they reduce the number of trig functions (which tend to use substantial computational resources).
Substantially any suitable threshold may be used at 110, for example, in a range from about 0.25 to about 2.5 degrees. In general increasing the value of the threshold reduces the error in the toolface value computed at 112. In one embodiment, a toolface error in a range from about 5-10 degrees may be achieved using a threshold value of 0.5 degrees. Using a threshold value of 1.0 degree may advantageously further reduce the toolface error. It will be understood that the threshold is related to the curvature of the wellbore section being drilled and the distance drilled. For example, at a curvature of 5 degrees per 100 feet of wellbore, a threshold of 0.5 degrees corresponds to a distance drilled of 10 feet. As such the control loop depicted in
It will be further understood that the measured value of β may be processed downhole to obtain an approximate rate of penetration ROP of drilling, for example, as follows:
where DLS represents the dogleg severity (curvature) of the borehole section being drilled and Δt represents the time passed between making measurements at the first and second upper and lower survey stations. This estimated ROP may be advantageously used, for example, to project the continuous survey sensor measurements to the bit (or other locations in the string). It will be understood that “static” and/or substantially continuous ROP values may be computed. For example, a static ROP may be computed at 112 when β exceeds the threshold. A substantially continuous ROP may be computed, for example, at 108 when computing β thereby giving a near instantaneous rate of penetration. Such a near instantaneous rate of penetration may optionally be filtered, for example, using a rolling average window or other filtering technique.
The reference and measured attitudes may be further processed at 112 to compute the GTF or MTF angles, for example, as follows:
An approximate GTF may be computed based on the assumption that β is small (e.g., less than about 5 degrees), for example, as follows:
Likewise, an approximate MTF may be computed when the borehole inclination is small (e.g., less than about 5 degrees) at the upper and lower survey stations, for example, as follows:
Equations 11 and 12 require less intensive computation and may therefore be advantageous when implementing the disclosed method on a downhole controller. It will be understood that the MTF and/or the GTF may alternatively (and/or additionally) be computed using other known mathematical relations, for example, utilizing inclination and magnetic dip angle or inclination, azimuth, and magnetic dip angle. Such mathematical relations are disclosed, for example, in U.S. Pat. No. 7,243,719 and U.S. Patent Publication 2013/0126239, each of which is incorporated by reference in its entirety herein.
The computed toolface values may be compared with a toolface set point value to compute toolface offset values (the error or offset between the set point value and the actual measured value) in substantially real time while drilling. The toolface offset values may be further processed to obtain a transfer function of the directional drilling system. This transfer function may be further evaluated in combination with various drilling and BHA parameters (e.g., formation type, rate of penetration, BHA configuration, etc) to evaluate the performance of the drilling system.
In the outer loop 220, the target azimuth targetAzi is combined at 222 with the measured azimuth cAzi from method 100 to obtain an azimuth error signal: e1 [n]=targetAzi−cAzi. The azimuth error signal is further combined at 224 with a weighted value of the measured inclination k sin(cInc) to obtain a weighted azimuthal error signal: e′1 [n]=e1 [n]·k·sin (cInc). Proportional and integral gains of the weighted azimuthal error signal are computed at 226 and 228 and combined at 230 to obtain a target toolface of the well: targetTF=kpAzi·e′1[n]+kiAzi·Σ1ne′1[n]. The target toolface may be either a GTF or a MTF and may be automatically (or manually) selected at 235, for example, based on the inclination of the wellbore.
In the inner loop 240 a target GTF or a target MTF are computed and input into control unit 260 that controls the direction of drilling. When the MTF/GTF switch 235 is set to select GTF, the target toolface of the well targetTF is combined at 242 with a GTF obtained from method 100 to obtain a GTF error signal: e3 [n]=targetTF−GTF. Proportional and integral gains of the GTF error signal are computed at 244 and 246 and combined at 248 to obtain the target GTF of the control unit: targetGTF=kpGTF·e3 [n]+kiGTF·Σ1ne3 [n]. When the MTF/GTF switch 235 is set to select MTF, the target toolface of the well targetTF is combined at 252 with an MTF obtained from method 100 to obtain an MTF error signal: e2 [n]=targetTF−MTF. Proportional and integral gains of the MTF error signal are computed at 254 and 256 and combined at 258 to obtain the target MTF of the control unit: targetMTF=kpMTF·e2 [n]+kiMTF·E1ne2 [n].
The methods described herein are configured for downhole implementation via one or more controllers deployed downhole (e.g., in a steering/directional drilling tool). A suitable controller may include, for example, a programmable processor, such as a microprocessor or a microcontroller and processor-readable or computer-readable program code embodying logic. A suitable processor may be utilized, for example, to execute the method embodiments described above with respect to
With continued reference to
Although closed loop control of drilling toolface and certain advantages thereof have been described in detail, it should be understood that various changes, substitutions and alterations may be made herein without departing from the spirit and scope of the disclosure as defined by the appended claims.
This application is a divisional of U.S. patent application Ser. No. 16/243,125, filed Jan. 9, 2019, which issues as U.S. Pat. No. 10,995,552 on May 4, 2021, which is a continuation of U.S. patent application Ser. No. 14/766,127, now U.S. Pat. No. 10,214,964 issued on Feb. 26, 2019, which is a national stage application of PCT Application No. PCT/US2014/031176 filed on Mar. 19, 2014, which claims priority to U.S. Provisional Patent Application No. 61/806,522 filed on Mar. 29, 2013, the entirety of each of which are incorporated herein by reference.
Number | Date | Country | |
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61806522 | Mar 2013 | US |
Number | Date | Country | |
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Parent | 16243125 | Jan 2019 | US |
Child | 17306567 | US |
Number | Date | Country | |
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Parent | 14766127 | Aug 2015 | US |
Child | 16243125 | US |