Claims
- 1. In a system for drilling a borehole in an underground formation, in which the system includes an elongated conduit extending from the surface through the borehole and a drill bit mounted at a forward end of the conduit for drilling the borehole through the formation, an improvement comprising a 3-D steering tool secured to the drill pipe for making inclination angle adjustments and azimuth angle adjustments at the drill bit during steering, including an onboard telemetry section to receive inclination angle and azimuth angle commands together with actual inclination angle and azimuth angle feedback signals during steering for use in controlling steering of the drill bit along a desired course; the 3-D steering tool comprising a rotary section and a flex section; in which the flex section includes an elongated drive shaft coupled to the drill bit and adapted to be rotatably driven for rotating the drill bit, the drive shaft being bendable laterally to define a deflection angle thereof, and a deflection actuator coupled to the drive shaft, the deflection actuator comprising a deflection housing surrounding the drive shaft and having a longitudinal axis and an elongated deflection piston movable in the deflection housing for applying a lateral bending force to the drive shaft for bending a wall section of the drive shaft away from the axis of the deflection housing while opposite end sections of the drive shaft are constrained by the housing for making changes in the deflection angle of the drive shaft which is transmitted to the drill bit as an inclination angle steering adjustment; in which the rotary section is coupled to the deflection actuator for transmitting a rotational force to the deflection actuator to rotate the deflection piston to thereby change the rotational angle at which the lateral bending force is applied to the drive shaft which is transmitted to the drill bit as an azimuth angle steering adjustment; and in which the telemetry section includes sensors for measuring the inclination angles and the azimuth angles of the steering tool while drilling, input signals proportional to the desired inclination angle and azimuth angle of the steering tool, and a feedback loop for processing measured and desired inclination angle and azimuth angle command signals for controlling operation of the deflection actuator for making inclination angle steering adjustments and for controlling operation of the rotary section for making azimuth angle steering adjustments.
- 2. The improvement according to claim 1 in which the conduit is an elongated rotary drill string.
- 3. The improvement according to claim 1 in which the conduit is a coiled tubing, and in which the drill bit is rotated by a downhole motor.
- 4. The improvement according to claim 1 in which the rotary section includes a rotator piston movable in proportion to the desired change in the azimuth angle and a helical gear arrangement on the deflection housing coupled to the rotator piston and rotatable in response to rotator piston travel to rotate the deflection housing and thereby rotate the deflection piston to change the azimuth angle at the drill bit.
- 5. The improvement according to claim 1 in which the lateral bending force is applied by a hydraulically powered bending force applied to the deflection piston by drilling mud taken from an annulus between the conduit and the borehole.
- 6. The improvement according to claim 1 in which the deflection actuator applies the bending force to the drive shaft while the rotary section applies the rotational force to the drive shaft for making simultaneous adjustments to the inclination angles and the azimuth angles.
- 7. The improvement according to claim 1 in which the feedback loop comprises a closed loop controller including a comparator for receiving the measured and desired inclination angle and azimuth angle command signals for producing inclination and azimuth error signals for making the steering adjustments.
- 8. The improvement according to claim 1 in which the telemetry section comprises an onboard mud pulse telemetry section for receiving the desired inclination and azimuth angle input signals and utilizing mud pulse controls for operating the deflection actuator and the rotary section from drilling mud taken from an annulus between the conduit and the borehole.
- 9. The improvement according to claim 8 in which the mud pulse telemetry section provides open loop control to the deflection actuator and the rotary section, and in which electrical controls provide closed loop control to the actuators.
- 10. The improvement according to claim 1 in which opposite ends of the drive shaft are supported by axially spaced-apart end bearings mounted adjacent opposite ends of the deflection housing, and the deflection piston applies the lateral bending force to the drive shaft between the end bearings to bend and thereby deflect the drive shaft into the deflection housing while the end bearings constrain the opposite ends of the drive shaft.
- 11. Apparatus according to claim 1 in which the deflection piston contained in the deflection housing is positioned on one side of the drive shaft and the drive shaft has a longitudinal axis aligned with a longitudinal axis of the deflection housing, and the lateral bending force is applied by the piston as a unitary force which physically bends the drive shaft to deflect its longitudinal axis away from the axis of the deflection housing.
- 12. A three-dimensional steering tool for use in drilling a borehole in an underground formation in which a rotary drill string extends from the surface through the borehole, and the steering tool is coupled to the rotary drill string at one end and to a drill bit at the other end for drilling the borehole, the steering tool comprising an integrated telemetry section, rotary section and flex section aligned axially along the steering tool for separately controlling inclination and azimuth angles at the drill bit; in which the flex section includes an elongated drive shaft coupled to the drill bit and adapted to be rotatably driven for rotating the drill bit, the drive shaft being bendable laterally to define a deflection angle thereof, and a deflection actuator coupled to the drive shaft, the deflection actuator comprising a deflection housing surrounding the drive shaft and having a longitudinal axis and an elongated deflection piston movable in the deflection housing for applying a lateral bending force to the drive shaft for bending a wall section of the drive shaft away from the axis of the deflection housing while opposite end sections of the drive shaft are constrained by the housing for making changes in the deflection angle of the drive shaft which is transmitted to the drill bit as an inclination angle steering adjustment; in which the rotary section is coupled to the deflection actuator and includes a rotator actuator for transmitting a rotational force to the deflection actuator to rotate the deflection piston to thereby change the rotational angle at which the lateral bending force is applied to the drive shaft which is transmitted to the drill bit as an azimuth angle steering adjustment; the telemetry section measuring present inclination angles and azimuth angles during drilling and comparing them with desired inclination and azimuth angle information to separately produce inclination control signals for operating the deflection piston and azimuth control signals for operating the rotator piston to make steering adjustments in azimuth.
- 13. Apparatus according to claim 12 in which the deflection actuator comprises an elongated deflection housing surrounding the drive shaft, and an elongated hydraulically operated piston in the deflection housing for applying a bending force distributed lengthwise along the drive shaft for flexing the drive shaft to change inclination angle at the drill bit.
- 14. Apparatus according to claim 12 in which the rotator actuator is coupled to the deflection housing and includes a linear piston movable in proportion to a desired change in azimuth angle and a helical gear arrangement on the deflection housing coupled to the linear piston and rotatable in response to piston travel to rotate the deflection housing to change azimuth angle at the drill bit.
- 15. Apparatus according to claim 14 in which the hydraulically powered bending force is applied to the deflection piston by drilling mud taken from an annulus between the conduit and the borehole.
- 16. Apparatus according to claim 12 in which the deflection actuator applies the bending force to the drive shaft while the rotator actuator applies the rotational force to the drive shaft for making simultaneous adjustments in inclination angle and azimuth angle.
- 17. Apparatus according to claim 12 in which the feedback loop comprises a closed loop controller including a comparator for receiving the measured and desired inclination angle and azimuth angle command signals for producing inclination and azimuth error signals for making the steering adjustments.
- 18. Apparatus according to claim 12 in which the telemetry section comprises an onboard mud pulse telemetry section for receiving desired inclination and azimuth angle signals from the surface and utilizing mud pulse controls for operating the deflection actuator and rotator actuator from drilling mud taken from an annulus between the conduit and the borehole.
- 19. Apparatus according to claim 12 in which the mud pulse telemetry section provides open loop control to the deflection actuator and the rotator actuator, and in which electrical controls provide closed loop control to the actuators.
- 20. Apparatus according to claim 12 in which opposite ends of the drive shaft are supported by axially spaced-apart end bearings mounted adjacent opposite ends of the deflection housing, and the deflection piston applies the lateral bending force to the drive shaft between the end bearings to bend and thereby deflect the drive shaft into the deflection housing while the end bearings constrain the opposite ends of the drive shaft.
- 21. Apparatus according to claim 12 in which the deflection piston contained in the deflection housing is positioned on one side of the drive shaft and the drive shaft has a longitudinal axis aligned with a longitudinal axis of the deflection housing, and the lateral bending force is applied by the piston as a unitary force which physically bends the drive shaft to deflect its longitudinal axis away from the axis of the deflection housing.
CROSS-REFERENCE TO RELATED APPLICATION
This application is a continuation of application Ser. No. 09/549,326, filed Apr. 13, 2000, now Pat. No. 6,470,974, which claims the priority of provisional application No. 60/129,194, filed Apr. 14, 1999, the entire disclosure of which is incorporated herein by reference.
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Provisional Applications (1)
|
Number |
Date |
Country |
|
60/129194 |
Apr 1999 |
US |
Continuations (1)
|
Number |
Date |
Country |
Parent |
09/549326 |
Apr 2000 |
US |
Child |
10/282481 |
|
US |