Patent Grant
8978698
1. Field of the Invention
This present invention relates generally to techniques for performing wellsite operations. More specifically, the present invention relates to techniques for monitoring the operation of blowout preventers (BOPs), for example, involving determining a ram block location.
2. Description of Related Art
Oilfield operations are typically performed to locate and gather valuable downhole fluids. Oil rigs are positioned at wellsites and downhole tools, such as drilling tools, are deployed into the ground to reach subsurface reservoirs. Once the downhole tools form a wellbore to reach a desired reservoir, casings may be cemented into place within the wellbore, and the wellbore completed to initiate production of fluids from the reservoir. Tubing or pipes are typically positioned in the wellbore to enable the passage of subsurface fluids to the surface.
Leakage of subsurface fluids may pose a significant environmental threat if released from the wellbore. Equipment, such as blow out preventers (BOPs), are often positioned about the wellbore to form a seal about pipes therein to prevent leakage of fluid as it is brought to the surface. In some cases, the BOPs employ rams and/or ram blocks that seal the wellbore. Some examples of ram BOPs and/or ram blocks are provided in U.S. Pat. Nos. 4,647,002, 6,173,770, 5,025,708, 7,051,989, 5,575,452, 6,374,925, 2008/0265188, 5,735,502, 5,897,094, 7,234,530 and 2009/0056132. The location of the ram and/or ram block of a BOP may be measured by visually looking at a tail shaft of the ram blocks. Ram position sensors may be provided as described, for example, in US Patent/Application No. 2008/0197306, U.S. Pat. No. 4,922,423, U.S. Pat. No. 5,320,325, U.S. Pat. No. 5,407,172, and U.S. Pat. No. 7,274,989.
Despite the development of techniques involving BOPs and/or ram blocks, there remains a need to provide advanced techniques for monitoring BOP operation. The present invention is directed to fulfilling these needs in the art.
In at least one aspect, the invention relates to a blowout preventer for sealing a tubular of a wellbore. The wellbore penetrates a subterranean formation. The blowout preventer has a housing having a bore therethrough for receiving the tubular, at least one ram slidably positionable in the housing (each of the rams having a ram block for sealing engagement about the tubular), an actuator for selectively driving the ram block (the actuator having a piston slidably positionable in a cylinder), and a monitor for detecting the piston therein. The monitor includes a visual indicator on an exterior of the cylinder. The visual indicator is operatively coupled to the piston for displaying a position of the piston as the piston travels within the cylinder whereby a position of the ram may be determined.
The visual indicator may have a cable operatively connected to the piston. The cable may be operatively connectable to a dial via a pulley and rotatable thereby as the piston moves within the cylinder. The visual indicator may also have at least one gear for operatively coupling the pulley to the dial. The visual indicator may have a magnetic coupler for coupling the dial to the pulley. The visual indicator may have a housing integral with the cylinder.
The visual indicator may also have a plurality of flags positioned on a flag rod. The plurality of flags may be selectively raisable as the piston passes adjacent thereto. The visual indicator may have a magnet slidably positionable on a guide in response to a magnet on the piston passing adjacent thereto. The visual indicator may have a transparent case with a plurality of metal filings movably positionable therein in response to a magnet on the piston passing adjacent thereto. The visual indicator may have a transparent case with a magnetic indicator movably positionable therein in response to a magnet on the piston passing adjacent thereto. The blowout preventer may also have a visual indicator sensor for detecting the visual indicator.
The blowout preventer may also have an electrical indicator for detecting a position of the piston. The electrical indicator may have a magnet slidably positionable on a guide in response to a magnet on the piston passing adjacent thereto, and at least one Hall Effect sensor for detecting a position of the magnet on the guide. The electrical indicator may be an inductive resistance sensor comprising a coil disposed about the cylinder. The electrical indicator may have a top end ultrasonic sensor at a top end of the cylinder and a bottom end ultrasonic sensor at a bottom end of the cylinder for detecting the piston when adjacent thereto. The electrical indicator may have an ultrasonic limit sensor. The electrical indicator may be a laser sensor. The electrical indicator may have a capacitive displacement sensor. The electrical indicator may be a sonar sensor for emitting sonar waves and sensing the waves rebounded by the piston. The electrical indicator may have at least one proximity sensor. The electrical indicator may have a flow sensor for detecting the flow of fluid through a chamber of the cylinder as the piston passes therein.
In yet another aspect, the invention relates to a system for sealing a tubular of a wellbore. The system has a blowout preventer and an inspector for inspecting visual indicator.
The blowout preventer has a housing having a bore therethrough for receiving the tubular, at least one ram slidably positionable in the housing (each of the rams having a ram block for sealing engagement about the tubular), an actuator for selectively driving the ram block (the actuator having a piston slidably positionable in a cylinder), and a monitor for detecting the piston therein. The monitor includes a visual indicator on an exterior of the cylinder. The visual indicator is operatively coupled to the piston for displaying a position of the piston as the piston travels within the cylinder whereby a position of the ram may be determined.
The blowout preventer has a housing having a bore therethrough for receiving the tubular, at least one ram slidably positionable in the housing (each of the rams having a ram block for sealing engagement about the tubular), an actuator for selectively driving the ram block (the actuator having a piston slidably positionable in a cylinder), and a monitor for detecting the piston therein. The monitor includes a visual indicator on an exterior of the cylinder. The visual indicator is operatively coupled to the piston for displaying a position of the piston as the piston travels within the cylinder whereby a position of the ram may be determined.
The inspector may be a human or a remote operated vehicle (ROV). The system may also have a surface unit for receiving data from the monitor, an electrical indicator for detecting a position of the piston, a receiver for communicating signals with the electrical indicator, and/or at least one sensor for detecting wellsite parameters.
In yet another aspect, the invention relates to a method of monitoring a blowout preventer. The method involves positioning the blowout preventer about a tubular, activating at least one of the visual indicators of the monitor as the piston passes adjacent thereto, and inspecting the visual indicators. The blowout preventer has a housing having a bore therethrough for receiving the tubular, at least one ram slidably positionable in the housing
(each of the rams having a ram block for sealing engagement about the tubular), an actuator for selectively driving the ram block (the actuator having a piston slidably positionable in a cylinder), and a monitor for detecting the piston therein. The monitor includes a visual indicator on an exterior of the cylinder. The visual indicator is operatively coupled to the piston for displaying a position of the piston as the piston travels within the cylinder whereby a position of the ram may be determined. The method may also involve sensing a position of the piston with an electrical indicator, manually viewing the visual indicators, sensing the visual indicator for activation, and/or passing data from the monitor to a surface unit.
Finally, in yet another aspect, the invention relates to a blowout preventer for sealing a tubular of a wellbore. The blowout preventer includes a housing having a bore therethrough for receiving the tubular, at least one ram slidably positionable in the housing (each of the at least one rams having a ram block for sealing engagement about the tubular), an actuator for selectively driving the ram block (the actuator comprising a piston slidably positionable in a cylinder), and a monitor for detecting the piston. The monitor has a housing with a cable therein. The cable is operatively connectable to the piston and movable therewith for activating a visual indicator on an exterior of the housing whereby a position of the ram may be displayed.
The monitor also may also have a sensor operatively connected for detecting movement of the cable and/or a communication link for passing data from the sensor to a surface unit. The visual indicator may have a dial rotationally movable by the cable. The monitor may also have a magnetic coupler inside of the housing for coupling the cable to the dial. The monitor also has at least one gear for operatively coupling the cable to the dial. The monitor may also have at least one pulley. The housing may be integral with the cylinder.
So that the above recited features and advantages of the present invention can be understood in detail, a more particular description of the invention, briefly summarized above, may be had by reference to the embodiments thereof that are illustrated in the appended drawings. It is to be noted, however, that the appended drawings illustrate only typical embodiments of this invention and are, therefore, not to be considered limiting of its scope, for the invention may admit to other equally effective embodiments. The Figures are not necessarily to scale and certain features, and certain views of the Figures may be shown exaggerated in scale or in schematic in the interest of clarity and conciseness.
The description that follows includes exemplary apparatus, methods, techniques, and instruction sequences that embody techniques of the present inventive subject matter. However, it is understood that the described embodiments may be practiced without these specific details.
The invention is directed at techniques for providing more effective monitoring and/or measuring of the operation of the blowout preventer (BOP). The BOP may be provided with a monitor to detect, for example, a position (or location) of a ram of the BOP. These techniques may be used to provide monitoring, such as visual or electrical monitoring, of the BOP from the surface, such as while the BOP is in use on the seabed. Such monitoring techniques involve one or more of the following, among others: determination of BOP function, determination of ram position, determination of sealed position, constant monitoring of the ram position within the BOP, adaptability to wellsite equipment (e.g., various pipes diameters).
A surface system 120 may be used to facilitate operations at the offshore wellsite 100. The surface system 120 may include a rig 122, a platform 124 (or vessel) and a surface controller 126. Further, there may be one or more subsea controllers 128. While the surface controller 126 is shown as part of the surface system 120 at a surface location and the subsea controller 128 is shown as part of the subsea system 106 in a subsea location, it will be appreciated that one or more controllers may be located at various locations to control the surface and/or subsea systems.
To operate one or more seal assemblies 102 and monitor the BOP monitoring system 103 and/or other devices associated with the wellsite 100, the surface controller 126 and/or the subsea controller 128 may be placed in communication therewith. The surface controller 126, the subsea controller 128, and/or any devices at the wellsite 100 may communicate via one or more communication links 134. The communication links 134 may be any suitable communication means, such as hydraulic lines, pneumatic lines, wiring, fiber optics, telemetry, acoustics, wireless communication, any combination thereof, and the like. The seal assembly 102, the BOP monitoring system 103, the BOP 108, and/or other devices at the wellsite 100 may be automatically, manually and/or selectively operated via the surface and subsea controllers 126 and/or 128, respectively.
A remove operated vehicle (ROV) 121 may optionally be provided to travel below the surface and inspect the BOP monitoring system 103. The ROV 121 may be provided with a camera 135 to display images of the BOP monitoring system 103 and/or electrical communicators (e.g., communication link 134) for coupling to the BOP monitoring system 103. The ROV 121 may be in communication with the surface unit 126 via a communication link 134. In some cases, a diver or other inspector may be used to visually inspect the BOP monitoring system 103.
The seal assembly 102 comprises one or more rams 202 for sealing the BOP 108. The rams 202 may be any suitable device for sealing the interior of the BOP 108 and/or severing the pipe 104, for example rams, ram blocks, and/or shearing blades. Upon actuation of the rams 202 of the seal assembly 102, the rams 202 may move along the channel 222 toward the pipe 104. The seal assembly 102 may seal the pipe 104 within the BOP 108, thereby preventing fluids, such as wellbore fluids and/or sea water, from passing through the BOP 108. Further, the seal assembly 102 may severe the pipe 104 if the seal assembly 102 has shearing blades.
The actuator 300 as shown, is a hydraulic actuator configured to move a piston 304 within a cylinder 306 using hydraulic fluid supplied to the actuator 300. The cylinder 306 has a side 307, a head 309 and a rear 311. The piston 304 is slidably movable within the cylinder 306 by, for example, hydraulic pressure selectively applied thereto. The piston 304 may couple to a rod 308 (or ram shaft) that is configured to move the rams 202 as piston 304 moves. Although the actuator 300 is shown as a hydraulic piston and cylinder, the actuator 300 may be any suitable actuator for moving the rams 202 between the actuated and the un-actuated positions.
As the piston 304 moves within the cylinder 306, the BOP monitoring system 103 may monitor the location of the piston 304. With the location of the piston 304 determined, the location of the rams 202 within the BOP 108 may be determined. The data collected by the BOP monitoring system 103 may be sent via the communication links 134 to the surface and subsea controller(s) 126/128 in order to, for example, determine how the BOP 108 is operating. The BOP monitoring system 103 may be any suitable system for determining the location of the pistons 304, the rods 308 and/or the rams 202 within the BOP 108. Preferably, the monitoring system 103 is also capable of determining other downhole parameters of the BOP 108, its components and/or associated downhole conditions.
The piston 304 travels within the cylinder 306 between the cylinder head 309 and the cylinder rear 311 of the BOP 108. The resistance in the coils 402 changes as a function of the location of the piston 304. The coils 402 may individually change as the piston 304 passes thereby, thus indicating that the piston 304 is adjacent to a certain coil 402. The changes in resistance may be used to determine the location of the piston 304 and the rod 308. Thus, the location of the rams 202 (as shown in
The piston magnet 416 may be any magnet secured to, or proximate the piston 304. As the piston 304 travels within the cylinder 306 between the cylinder rear 311 and the cylinder head 309, the piston magnet 416 raises the magnet flags 412 proximate the piston 304. The raised magnet flags 412 may be used to provide a visual indication of the location of the piston 304 and the rod 308. Thus, the location of the rams 202 (as shown in
As the piston 304 travels within the cylinder 306 between the cylinder rear 311 and the cylinder head 309, the piston 304 with a magnet 416 thereon translates the sliding magnet 420 proximate the piston 304. The location of the sliding magnet 420 may provide a visual indicator of the piston 304. Limit switches or other devices, such as sensor S, may also be used to detect and/or communicate the position of the sliding magnet 420 along the guide rod 422. The sliding magnet 420 location may be used to determine the location of the piston 304 and the rod 308. Thus, the location of the rams 202 (as shown in
Changes in the ultrasonic waves 428 may indicate the location of the piston 304 proximate to one or more of the ultra sonic inducers 426. As the piston 304 travels within the cylinder 306 between the cylinder rear 311 and the cylinder head 309, the detected changes in the ultrasonic waves 428 may be used to determine the location of the piston 304 and the rod 308. Thus, the location of the rams 202 (as shown in
A visual indicator, such as those provided herein, may also optionally be coupled to the monitoring system 103d to provide a visual indication of position upon activation by the monitoring system 103d.
Each of the ultrasonic inducers 426, 427 produce the ultrasonic waves 428 that are directed into an interior of the cylinder 306 and then detected by a receiver 429. Changes in the ultrasonic waves 428 may indicate the location of the piston 304 proximate to the ultra sonic inducer 426, 427. As the piston 304 travels within the cylinder 306 between the cylinder rear 311 and the cylinder head 309, the detected changes in the ultrasonic waves 428 indicate when the piston 304 reaches the travel limits in either the un-actuated position or the actuated position. Therefore, the detected changes in the ultrasonic waves 428 may be used to determine a position of the piston 304 and the rod 308. Thus, the location of the rams 202 (as shown in
The sensor S may pass the signal to various components, such as receiver 429, for communicating a position of the piston 304. A visual indicator, such as those provided herein, may also optionally be coupled to the monitoring system 103e to provide a visual indication of position upon activation by the monitoring system 103e.
The laser 436 may engage a portion of the piston 304. The laser 436 may have conventional range finding capabilities that may be used to determine the distance between the cylinder rear 311 and the piston 304 as the piston travels within the cylinder 306. The piston 304 location as determined by the laser sensor 432 may be used to determine the location of the piston 304 and the rod 308. Thus, the location of the rams 202 (as shown in
As the piston 304 travels within the cylinder 306 between the cylinder rear 311 and the cylinder head 309, the linear sensor 444 detects the location of the piston magnet 416. The piston magnet 416 location may be used to determine the location of the piston 304 and the rod 308. Thus, the location of the rams 202 (as shown in
Proximity sensors 421 may be positioned on either side of sliding magnet 420 to detect the position of the sliding magnet. The magnet 420 may be detected by the proximity sensors 421 as the magnet approaches thereby indicating the position of the piston 304. Therefore, the Hall Effect sensor 448 may provide a specific electrical and/or visual indication of the piston 304 and the rod 308 position or location. Thus, the location of the rams 202 (as shown in
As shown in
The transparent case 454 may have any suitable form for allowing the magnetic indicator 452 to travel. The transparent case 454 may be transparent to allow for visual inspection of the location of the magnetic indicator 452, as the magnetic indicator 452 travels within the transparent case 454. The magnetic indicator 452 may be used to provide a visual indication of the location of the piston 304 and the rod 308. As the piston 304 travels within the cylinder 306 between the cylinder rear 311 and the cylinder head 309, a piston magnet 416 on piston 304 translates the magnetic indicator 452 through the transparent case 454 to a position proximate the piston 304. The magnetic indicator 452 location may be used to determine the location of the piston 304 and the rod 308. Thus, the location of the rams 202 (as shown in
As the piston 304 travels within the cylinder 306 between the cylinder head 309 and the rear 311 of the BOP 108, the piston magnet 416 translates the magnetic indicator 453 proximate the piston 304. The magnetic indicator 453 location within the transparent tube may be used to provide a visual indication of the location of the piston 304 and the rod 308. Thus, the location of the rams 202 (as shown in
As the piston 304 moves from the un-actuated position to the actuated position, the cable 460 may be pulled by the piston 304. The cable 460 movement may rotate one or more gears 462 located within the gear drive housing 458. One of the gears 462 may couple to and/or rotate a first portion of a magnetic coupler 464 located within the gear drive housing 458.
The first portion of the magnetic coupler 464 may magnetically couple to a second portion of the magnetic coupler 466 located outside of the gear drive housing 458.
The rotation of the second portion of the magnetic coupler 466 may be measured and used to determine the location of the piston 304 as it travels within the cylinder 306. An indicator arrow 467 may be positioned on the magnetic coupler 466 and rotated therewith. The position of the indicator arrow 467 may be used as an electrical and/or visual indicator to indicate the position of the piston 304. As shown in
The gears 462 may be spring wound in order to retract the cable 460 when the piston 304 travels from the actuated position to the un-actuated position. The piston 304 location as visually indicated by the indicator arrow 467 may be used to determine the location of the piston 304 and rod 308. Thus, the location of the rams 202 (as shown in
The rotation of the second portion of the magnetic coupler 466 may be measured and used to determine the location of the piston 304 and the rod 308 as it travels within the cylinder 306 in a similar manner as that described for
The rotation of the second portion of the magnetic coupler 466 may be measured and used to determine the location of the piston 304 and the rod 308 as it travels within the cylinder 306 in a similar manner as that described for
The movement of arrow 467 may be detected by a sensor S. The sensor S may also be operatively coupled to the monitoring system 103k-m to provide an electrical or visual indication of the position of the arrow 467. The sensor S may pass the signal to various components for communicating a position of the piston 304.
As shown in each of these figures, the piston 304 is slidably movable within the cylinder 306. In these figures, for simplicity, the rod 308 is not shown. The monitoring systems 103m-p are each positionable about the cylinder 306 and have devices for detecting a position of the piston 304 therein. Each piston 304 is operatively connectable to a ram 202 (see
A sensor electrode 506 may detect the current after the current has engaged the piston 304. Changes in the current detected by the sensor electrode 506 may be used to determine the distance of the piston 304 from the cylinder rear 311. The piston 304 location may be used to determine the location of the piston 304 (and the rod 308 not shown). Thus, the location of the rams 202 (as shown in
The sonic wave 510 may be propagated into the cylinder 306 and reflected off of the piston 304. The reflected sonic wave 510 may be detected by a receiver 512.
Changes in the detected sonic wave 510 may be used to determine the distance of the piston 304 from the cylinder rear 311. The piston 304 location may be used to determine the location of the piston 304 (and rod 308 not shown). Thus, the location of the rams 202 (as shown in
The proximity sensor(s) 514 may detect the location of the piston 304 when the piston 304 is in the actuated and/or un-actuated position. There may also be multiple proximity sensor(s) 514 along the cylinder 306 in order to give the location of the piston 304 as the piston 304 translates within the cylinder 306. The piston 304 location may be used to determine the location of the piston 306 (and rod 308 not shown). Thus, the location of the rams 202 (as shown in
Pumps, flowlines or other fluid devices may be provided to assist in manipulating the flow of fluid through the flow sensor 516.
With the inner volume of the cylinder known, the hydraulic flow into the cylinder may be used to calculate the position of the piston 304 within the cylinder. Alternatively, when the piston 304 is retracted toward the un-actuated position, the mechanical flow meter may reset back to zero instead of measuring the outflow. The piston 304 location may be used to determine the location of the piston 304 (and rod 308 not shown). Thus, the location of the rams 202 (as shown in
Each of the monitors 103a-p depicted in
It will be appreciated by those skilled in the art that the techniques disclosed herein can be implemented for automated/autonomous applications via software configured with algorithms to perform the desired functions. These aspects can be implemented by programming one or more suitable general-purpose computers having appropriate hardware. The programming may be accomplished through the use of one or more program storage devices readable by the processor(s) and encoding one or more programs of instructions executable by the computer for performing the operations described herein. The program storage device may take the form of, e.g., one or more floppy disks; a CD ROM or other optical disk; a read-only memory chip (ROM); and other forms of the kind well known in the art or subsequently developed. The program of instructions may be “object code,” i.e., in binary form that is executable more-or-less directly by the computer; in “source code” that requires compilation or interpretation before execution; or in some intermediate form such as partially compiled code. The precise forms of the program storage device and of the encoding of instructions are immaterial here. Aspects of the invention may also be configured to perform the described functions
(via appropriate hardware/software) solely on site and/or remotely controlled via an extended communication (e.g., wireless, internet, satellite, etc.) network.
While the embodiments are described with reference to various implementations and exploitations, it will be understood that these embodiments are illustrative and that the scope of the inventive subject matter is not limited to them. Many variations, modifications, additions and improvements are possible. For example, one or more monitors may be positioned about one or more cylinders of a blowout preventer. Also, the monitoring devices described herein may detect positions of the piston 304 (and other portions of the ram 202) in an unactuated position, an actuated position, and/or all other positions therebetween.
Plural instances may be provided for components, operations or structures described herein as a single instance. In general, structures and functionality presented as separate components in the exemplary configurations may be implemented as a combined structure or component. Similarly, structures and functionality presented as a single component may be implemented as separate components. These and other variations, modifications, additions, and improvements may fall within the scope of the inventive subject matter.
This application claims the benefit of U.S. Provisional Application No. 61/360,783 filed on Jul. 1, 2010, the entire contents of which are hereby incorporated by reference.
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