The present invention relates to the field of steering assemblies used for downhole directional drilling. The prior art discloses directional drilling drill bit assemblies.
U.S. Pat. No. 5,553,678 to Barr et al., which is herein incorporated by reference for all that it contains, discloses a modulated bias unit is provided for controlling the direction of drilling of a rotary drill bit when drilling boreholes in subsurface formations. The unit comprises a plurality of hydraulic actuators spaced apart around the periphery of the unit and having movable thrust members hydraulically displaceable outwardly for engagement with the formation of the borehole being drilled. Each actuator has an inlet passage for connection to a source of drilling fluid under pressure and an outlet passage for communication with the annulus. A selector control valve connects the inlet passages in succession to the source of fluid under pressure, as the unit rotates, and a choke is provided to create a pressure drop between the source of fluid under pressure and the selector valve. A further choke is provided in the outlet passage from each actuator unit. The actuators and control valve arrangements may take a number of different forms.
U.S. Pat. No. 4,416,339 to Baker et al., which is herein incorporated by reference for all that it contains, discloses a mechanism and method for positive drill bit guidance during well drilling operations. The guidance device includes a control arm or paddle which, due to hydraulic pressure, pivots to steer the drill bit towards its target area. As the paddle applies pressure to the wall of the well, the drill bit is then turned from the contacted area of the well wall in the desired direction.
U.S. Pat. No. 5,582,259 to Barr et al., which is herein incorporated by reference for all that it contains, discloses a modulated bias unit, for controlling the direction of drilling of a rotary drill bit when drilling boreholes in subsurface formations, comprises a number of hydraulic actuators spaced apart around the periphery of the unit. Each actuator comprises a movable thrust member which is hydraulically displaceable outwardly and a formation-engaging pad which overlies the thrust member and is mounted on the body structure for pivotal movement about a pivot axis located to one side of the thrust member. A selector control valve modulates the fluid pressure supplied to each actuator in synchronism with rotation of the drill bit so that, as the drill bit rotates, each pad is displaced outwardly at the same selected rotational position so as to bias the drill bit laterally and thus control the direction of drilling. The pivot axis of the formation-engaging member is inclined to the longitudinal axis of rotation of the bias unit so as to compensate for tilting of the bias unit in the borehole during operation.
In one aspect of the present invention, a downhole rotary steerable system comprises a fluid cavity defined by a bore formed within a drill string component. A valve may be located within the wall of the bore, which hydraulically connects the bore with the fluid cavity. A steering nozzle may be disposed on the drill string component and in communication with the fluid cavity. The valve is configured to control flow from the bore to the fluid cavity and an azimuthal sensing mechanism may be configured to determine the azimuth of the steering nozzle. Instrumentation may be configured to control the valve based off of input from the azimuthal sensing mechanism.
The azimuthal sensing mechanism may comprise a plurality of accelerometers configured to transmit a signal to the instrumentation that actuates the valve through the use of a motor. The azimuthal sensing mechanism may also comprise at least one magnetometer which measures azimuth position, wherein the azimuthal sensing mechanism is configured to calibrate the valve using the input from the magnetometer. The steerable system may further comprise at least one expandable element supported by the drill string component and in communication with at least one fluid cavity. The expandable element may be disposed opposite the steering nozzle on the drill string element.
The diameter of the steering nozzle may be smaller than the diameter of the valve such that a pressure differential is created that forces the expandable element to extend and results in ejecting the fluid through the steering nozzle at the formation with increased force. The expandable element may be configured to shift the center axis of the drill string away from the center axis of the borehole. Each expandable element and steering nozzle may be in fluid communication with a steering nozzle and expandable element.
The instrumentation may be configured to actuate each valve separately. The valve may be configured to be actuated by a motor powered by a turbine generator. The turbine generator may also be configured to power the azimuthal sensing mechanism. The valve, azimuthal sensing mechanism, and instrumentation may be disposed within a housing. The housing may be inserted into the bore of the drill string component and the fluid cavity may comprise an annular shape formed between the housing and the drill string component.
a is a perspective view of an embodiment of a steerable system.
b is a cross-sectional view of an embodiment of a steerable system.
a is a cross-sectional view of an embodiment of a steerable system.
b is a cross-sectional view of an embodiment of a steerable system.
a is a cross-sectional view of another embodiment of a steerable system.
b is a cross-sectional view of another embodiment of a steerable system.
a is a cross-sectional view of another embodiment of a steerable system.
b is a cross-sectional view of another embodiment of a steerable system.
a is a cross-sectional view of an embodiment of a retraction mechanism.
b is a cross-sectional view of another embodiment of a retraction mechanism.
Referring now to the figures,
a and 4b are perspective and cross-sectional views of another embodiment of a steerable system 103. The system 103 may comprise an expandable element 205 disposed on a drill string 100 attached to a drill bit 104. The drill string 100 may comprise a generally outer annular surface, and the steering nozzle 301 and the expandable element 205 may both be supported by the generally outer annular surface, but positioned opposite each other. In some embodiments the steering nozzle may be disposed on a gauge of a drill bit.
A housing 401 that contains some of the mechanism in the steering system may be inserted into the bore of the drill string 100. O-rings 403 may provide a fluid seal between the housing 401 and the inner surface of the drill string's bore. The housing 401 may comprise a cylindrical geometry (or another geometry complimentary to the inner surface of the bore). The thickness of the housing wall may comprise a motor 405 to operate a valve 407, the valve 407, an orientation sensing mechanism instrumentation 409, and part of an expandable element 205. The orientation sensing mechanism may comprise instrumentation that determines the azimuth of the drill string component. The orientation/azimuthal sensing mechanism may comprise an accelerometer 411 and a magnetometer 413.
The expandable element 205 may extend through an opening in a side of the drill string 100. The opening in the drill string may correspond with an opening in the housing. As fluid is directed towards a surface 449 on a back end 450 of the expandable element 205, the fluid cavity may be pressurized and fluid pressure may exert a force on the surface 449 of the back end 450 to extend the expandable element 205. Seals 451 disposed between the opening wall and the expandable element may prevent leaks. In some embodiments, a small leak is acceptable to keep debris from clogging the interference between the expandable element and the opening. Also, a stopping mechanism may be incorporated into the present invention to retain the expandable element within the opening while allowing the expandable element to translate within the opening.
The motor 405 may be mechanically connected to the valve 407. The instrumentation 409 may be in electrical communication with the motor 405, and thus, control the valve. In the present embodiment, the orientation sensing mechanism may be an azimuthal sensing mechanism configured to detect the orientation of the drill bit 104 downhole and transmit that data to the instrumentation 409 through the use of at least one accelerometer and magnetometer 411, 413. A processing element of the instrumentation 409 may compute when to activate the motor 405 based on this downhole data or from a separate input received from the surface.
Accelerometers may be used to track the azimuth of the nozzle and expandable element. In some embodiments, a magnetometer may be used to compensate for rotational drift defined as a gradually increasing inconsistency between the accelerometer readings and the actual location of the nozzles and expandable element. The instrumentation 409 may be configured to compensate for timing delays between the acquisition of data and actuation of the valve as well as the delay between the actuation of the valve and the actuation of the expandable element, thus, facilitating a more precise change in direction while drilling.
a and 5b are cross-sectional views of an embodiment of a steerable system 103.
The valve 407 may comprise a plurality of ports 505 configured to direct fluid from the bore 503 of the drill string to the compressible fluid cavity 501. The ports 505 may be aligned with the bore 503 through the use of a motor 405. As the motor 405 rotates the valve 407, the ports 505 may open and close to the bore 503. When open, the valve directs a portion of the drilling fluid from the bore 503 and into the compressible fluid cavity 501. The valve 407 may be a rotary valve, ball valve, butterfly valve, or any valve that can be used to regulate fluid.
The fluid may enter the compressible fluid cavity 501 and be directed to a steering nozzle 301 and an expandable element 205. The path to the expandable element 205 may comprise a larger cross sectional area than the steering nozzle 301, thus, directing more fluid to the expandable element 205 than to the steering nozzle 301. In some embodiments, the back end of the expandable element may comprise a greater area than the opening in the steering nozzle. The expandable element 205 may come into contact with the earthen formation directing the drill string in the opposite direction of the earthen formation while forcing more fluid through the steering nozzle 301. The steering nozzle 301 may comprise a smaller diameter than the ports 505 creating a greater pressure differential in the compressible fluid cavity 501 from the restriction of fluid passing through the steering nozzle 301. The greater pressure differential may result in the fluid from the steering nozzle 301 being directed at a greater velocity than the fluid from the drilling nozzles 303.
a and 11b are cross-sectional views of another embodiment of a steerable system 103. The system 103 may comprise a reciprocating valve 1101 configured to direct all fluid to the at least one steering nozzle 301 disposed on the side of the drill bit 104 or to direct all drilling fluid to the at least one drilling nozzle 303 disposed on the working face of the drill bit 104.
a discloses the valve 1101 open to the bore of the drill string and directing fluid to the expandable element and the steering nozzle. However, the geometry of the valve also simultaneously blocks fluid from the face, drilling nozzles. Thus, while the fluid is directed to the steering nozzles, the fluid is also temporarily blocked to the face, drilling nozzles. Such an arrangement many provide at least two advantages. First, more hydraulic power may be provided to the steering nozzle and expandable element. Second, the fluid ejected from the face, drilling nozzles may have a lower propensity to interfere with the fluid ejected from the steering nozzle. Third, the temporary blockage may induce a vibration in the fluid ejected from the face, drilling nozzles, which may provide an additional destructive force into the formation.
a and 12b disclose a reciprocating valve 1201 configured to alternate drilling fluid between a fluid cavity 501, and thus to the steering nozzle and expandable element, and to a single drilling nozzle 1203 disposed nearby the steering nozzle 301.
a and 13b disclose a retraction mechanism 1301 disposed adjacent an expandable element 1303. The retraction mechanism 1301 may comprise a compression spring, a tension spring, a spring mechanism, or a hydraulic mechanism.
b discloses a retraction mechanism 1301 comprising a hydraulic mechanism 1307. As the valve 407 closes, fluid may be directed into a hydraulic chamber 1307 that, when pressurized, returns the expandable element to its retracted position.
Whereas the present invention has been described in particular relation to the drawings attached hereto, it should be understood that other and further modifications apart from those shown or suggested herein, may be made within the scope and spirit of the present invention.
This application is a continuation of U.S. patent application Ser. No. 13/048,595, which was filed on Mar. 15, 2011 and is herein incorporated by reference for all that it contains.
Number | Date | Country | |
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Parent | 13048595 | Mar 2011 | US |
Child | 13048707 | US |