This section is intended to introduce the reader to various aspects of art that may be related to various aspects of the present disclosure, which are described and/or claimed below. This discussion is believed to be helpful in providing the reader with background information to facilitate a better understanding of the various aspects of the present disclosure. Accordingly, it should be understood that these statements are to be read in this light, and not as admissions of prior art.
A blowout preventer (BOP) stack is installed on a wellhead to seal and control an oil and gas well during drilling operations. A drill string may be suspended inside a drilling riser from a rig through the BOP stack into the wellbore. During drilling operations, a drilling fluid is delivered through the drill string and returned up through an annulus between the drill string and a casing that lines the wellbore. In the event of a rapid invasion of formation fluid in the annulus, commonly known as a “kick,” a movable component within the BOP stack may be actuated to seal the annulus and to control fluid pressure in the wellbore, thereby protecting well equipment disposed above the BOP stack.
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 determining or limiting the scope of the claimed subject matter as set forth in the claims.
In some embodiments, a remote locking system for a blowout preventer (BOP) includes a locking mechanism, such that the locking mechanism can be remotely actuated to lock the BOP. In some embodiments, the remote locking system includes a locking mechanism configured to move to adjust the remote locking system between an unlocked configuration in which the remote locking system enables movement of a ram of the BOP and a locked configuration in which the remote locking system blocks movement of the ram of the BOP. The remote locking system also includes a gear assembly coupled to the locking mechanism, a motor coupled to the gear assembly, and an electronic controller configured to provide a control signal to activate the motor to drive the locking mechanism to move via the gear assembly.
Various features, aspects, and advantages of the present disclosure will become better understood when the following detailed description is read with reference to the accompanying figures in which like characters represent like parts throughout the figures, wherein:
One or more specific embodiments of the present disclosure will be described below. These described embodiments are only exemplary of the present disclosure. Additionally, in an effort to provide a concise description of these exemplary embodiments, all features of an actual implementation may not be described in the specification. It should be appreciated that in the development of any such actual implementation, as in any engineering or design project, numerous implementation-specific decisions must be made to achieve the developers' specific goals, such as compliance with system-related and business-related constraints, which may vary from one implementation to another. Moreover, it should be appreciated that such a development effort might be complex and time consuming, but would nevertheless be a routine undertaking of design, fabrication, and manufacture for those of ordinary skill having the benefit of this disclosure.
The present disclosure is generally directed to blowout preventers (BOPs). In particular, the present disclosure is generally directed to a remote locking system for a BOP and/or a method for remote locking of a locking mechanism (e.g., lock screw) for the BOP. The remote locking system may be configured to adjust between an unlocked configuration in which the remote locking system enables movement of rams of the BOP and a locked configuration in which the remote locking system blocks movement of the rams of the BOP.
The BOP is one of the most popular and widely used products to control fluid pressures in a wellbore. A ram-type BOP may generally include a housing, which may be attached to a well casing and which may be provided with a central bore (e.g., a passageway through the BOP) through which a conduit (e.g., drill string) may be passed. Carried in the housing is a pair of rams, which are disposed for reciprocal movement between a retracted position and an extended position. The retracted position corresponds to an open configuration for the BOP, and the extended position corresponds to a closed configuration for the BOP. In the retracted position, an annular area between the conduit and the well casing is open. In the extended position, the rams engage an exterior of the conduit and sealingly close the annular area between the conduit and the well casing.
The rams may each be connected by a respective rod to a respective piston and cylinder assembly carried by the housing. To close the BOP (e.g., to move the rams into the extended position), pressure is applied to the piston and cylinder assembly to thereby force the rams into sealing engagement with the conduit. To open the BOP (e.g., to move the rams into the retracted position), pressure is applied to an opposite end of the piston and cylinder assembly to thereby force the rams out of the central bore.
While the BOP is in the closed configuration, it may be desirable to lock the rams (e.g., to block movement of the rams). Otherwise, extreme pressures would be maintained on the piston and cylinder assemblies of the BOP to hold the BOP in the closed configuration, for example. Some existing BOPs may use a manually operated locking screw that, when screwed in place, engages a portion (e.g., “tail rod” attached to the piston) of the piston of the piston and cylinder assembly, thereby blocking return of the rams to the retracted position.
This type of manually-operated locking screw may require a long period of time to engage the tail rod. Further, operating the manually operated locking screw in certain applications, such as offshore applications, might be impractical or impossible. Finally, decreasing an amount of manually operated devices on or in proximity of a drill floor may be desirable to decrease costs, for example. Accordingly, it is presently recognized that it may be desirable to enable locking of the rams, whether in offshore or in onshore applications, using a remotely operated locking device that could be installed on newly commissioned systems (e.g., drilling systems) and/or retrofitted on already existing systems (e.g., drilling systems).
While certain embodiments disclosed herein relate to an offshore system (e.g., subsea system) to facilitate discussion, it should be understood that the BOP and the remote locking system may be used in an on-shore system (e.g., land-based system). Furthermore, while certain embodiments disclosed herein relate to a drilling system that may be used to carry out drilling operations to facilitate discussion, it should be appreciated that the BOP and the remote locking system may be adapted for use in any of a variety of contexts and during any of a variety of operations. For example, the BOP and the remote locking system may be used in a production system and/or in a pressure control equipment (PCE) stack that is positioned vertically above a wellhead during various intervention operations (e.g., inspection or service operations), such as wireline operations in which a tool supported on a wireline is lowered through the PCE stack to enable inspection and/or maintenance of a well. In such cases, the BOP may be adjusted from the open configuration to the closed configuration (e.g., to seal about the wireline extending through the PCE stack) to isolate the environment, as well as other surface equipment, from pressurized fluid within the well. In the present disclosure, a conduit may be any of a variety of tubular or cylindrical structures, such as a drill string, wireline, Streamline™, slickline, coiled tubing, or other spoolable rod.
The BOP stack 20 may include one or more BOPs 28 stacked along the vertical axis 2 relative to one another. One or more of the BOPs 28 may include opposed rams that are configured to move along the axial axis 4 toward and away from one another to adjust the BOP 28 between an open configuration and a closed configuration. In the open configuration, the opposed rams may be retracted (e.g., withdrawn) from a central bore of the BOP 28, and thus, the BOP 28 may enable fluid flow through the central bore. In the closed configuration, the opposed rams may be extended into (e.g., positioned in) the central bore of the BOP 28, and thus, the BOP 28 may block fluid flow through the central bore.
The BOP stack 20 may include any suitable number of BOPs 28. Additionally, the BOP stack 20 may include any of a variety of different types of BOPs 28 (e.g., having shear rams, blind rams, blind shear rams, pipe rams). For example, in certain embodiments, the BOP stack 20 may include one or more BOPs 28 having opposed shear rams or blades configured to sever the conduit 24 to block fluid flow through the central bore and/or one or more BOPs 28 having opposed pipe rams configured to engage the conduit 24 to block fluid flow through the central bore (e.g., through an annulus about the conduit 24).
As shown, the BOP stack 20 may include one or more remote locking assemblies 30 (e.g., remote locking apparatuses). For example, one remote locking assembly 30 may be positioned at each end (e.g., along the axial axis 4) of the BOP 28. The remote locking assembly 30 may be part of a remote locking system 32 that operates to adjust components of the remote locking assembly 30 between an unlocked configuration in which the remote locking assembly 30 enables movement of the rams of the BOP 28 and a locked configuration in which the remote locking assembly 30 blocks movement of the rams of the BOP 28. In operation, while the BOP 28 is in the open configuration, the closed configuration, and/or any position therebetween, the remote locking assembly 30 may be in the locked configuration to maintain the BOP 28 in the open configuration, the closed configuration, and/or the position therebetween. However, the remote locking assembly 30 may be adjusted to the unlocked configuration to enable the rams of the BOP 28 to move relative to the central bore to move between the open configuration and the closed configuration. For example, in response to an indication of an increased pressure within the wellbore 26 or another indication (e.g., operator input; test cycle) that the rams of the BOP 28 should be moved from the open configuration to the closed configuration, the rams of the BOP 28 may be moved from the open configuration to the closed configuration and the remote locking system 32 may operate to adjust the remote locking assembly 30 from the unlocked configuration to the locked configuration to maintain the rams of the BOP in the closed configuration, thereby facilitating maintenance of a seal across the central bore of the BOP 28.
As discussed in more detail below, the remote locking system 32 may include a controller 34 (e.g., electronic controller) having a processor 36 and a memory device 38. In some embodiments, the processor 36 may receive and process signals from a sensor that monitors the pressure within the wellbore 26 to determine that the BOP 28 should be adjusted from the open configuration to the closed configuration (or vice versa). In some embodiments, the processor 36 may receive other signals (e.g., operator input) that indicate that the BOP 28 should be adjusted from the open configuration to the closed configuration (or vice versa). Then, the processor 36 may provide control signals, such as to an actuator assembly to adjust the rams to move toward one another and into the central bore to reach the closed configuration. The processor 36 may also provide control signals, such as to one or more motors (e.g., hydraulic motors, pneumatic motors, electric motors) of the one or more remote locking assemblies to drive adjustment of one or more locking mechanisms (e.g., lock screws) to lock the rams in the closed configuration.
The controller 34 may be part of or include a distributed controller or control system with one or more electronic controllers in communication with one another to carry out the various techniques disclosed herein. For example, the controller 34 may be part of a distributed controller with one controller at the vessel or platform 12 and another controller 34 at the BOP 28 and/or at the remote locking assembly 30. The processor 36 may also include one or more processors configured to execute software, such as software for processing signals and/or controlling other components associated with the remote locking system 32 and/or the BOP 28. The memory device 38 disclosed herein may include one or more memory devices (e.g., a volatile memory, such as random access memory [RAM], and/or a nonvolatile memory, such as read-only memory [ROM]) that may store a variety of information and may be used for various purposes. For example, the memory device 38 may store processor-executable instructions (e.g., firmware or software) for the processor 36 to execute, such as instructions for processing signals and/or controlling the other components associated with the remote locking system 32 and/or the BOP 28. It should be appreciated that the controller 34 may include various other components, such as a communication device 40 that is capable of communicating data or other information to various other devices via a wired and/or a wireless connection.
Advantageously, the remote locking system 32 having the controller 34 enables the one or more remote locking assemblies 30 to be efficiently and remotely locked via electronic control (e.g., without a human operator, a remotely-operated vehicle [ROV], or an autonomously-operated vehicle [AUV] physically contacting and manipulating the one or more remote locking assemblies 30 or the one or more locking mechanism at the BOP 28). The remote locking system 32 herein also enables smooth and/or continuous application of torque to the locking mechanism 70 during an unlocking operation and a locking operation, as opposed to some types of manual operation that may not enable smooth and/or continuous application of torque. Additionally, the remote locking system 32 may provide a visual indicator (e.g., visible to a human operator, a ROV, or an AUV) of a configuration of the one or more remote locking assemblies 30, such as due to respective positions of each of the one or more locking assemblies 30 relative to components of the BOP 28 (e.g., because visible portions of the one or more locking assemblies 30 move relative to components of the BOP 28 during the unlocking operation and the locking operation. The remote locking system 32 may remain coupled to the BOP 28 during operations (e.g., drilling operations) and/or may be a stand-alone component is supported only by to the BOP 28 (e.g., not part of an ROV or an AUV).
As shown, a respective remote locking assembly 30 is supported by and/or coupled to each bonnet 60. Each remote locking assembly 30 is configured to adjust (e.g., via actuation, such as hydraulic actuation) from an unlocked configuration in which the remote locking assembly 30 enables movement of one of the rams 50 of the BOP 28 and a locked configuration in which the remote locking assembly 30 blocks movement of the one of the rams 50 of the BOP 28. Each remote locking assembly 30 includes or is configured to drive a locking mechanism 70 (e.g., lock screw; remotely actuated engagement mechanism) that is configured to move relative to the rams 50, the central bore 56, and/or the bonnet 60. In the illustrated embodiment, the locking mechanism 70 is threadably coupled to the bonnet 60 such that rotation of the locking mechanism 70 drives the locking mechanism 70 to move along the axial axis 4 relative to the bonnet 60. For example, the locking mechanism 70 may be rotated in a first direction (e.g., along the circumferential axis 8) to drive the locking mechanism 70 toward the ram 50 and toward the central bore 56 while the ram 50 is in the closed configuration to thereby contact the piston 64 (e.g., a surface of the piston 64, a “tail rod” of the piston 64) and to lock the ram 50 in the closed configuration. The locking mechanism 70 may be rotated in a second direction (e.g., opposite the first direction along the circumferential axis 8) to drive the locking mechanism 70 away the ram 50 and away the central bore 56 to thereby enable the ram 50 to be adjusted from the closed configuration toward the open configuration 54. As shown, a central or rotational axis of the locking mechanism 70 extends along the axial axis 4.
It should be appreciated that the remote locking assembly 30 may not include the locking mechanism 70 (e.g., during manufacture and/or installation of the remote locking assembly 30), and instead, the remote locking assembly 30 may be retrofitted and used with the locking mechanism 70 that is already installed on any of a variety of existing BOPs 28 (e.g., in use and/or installed within the field), such as with the locking mechanism 70 that is configured to be manually operated (e.g., via rotation by a human operator, an ROV, an AUV) in the absence of the remote locking assembly 30. Thus, the remote locking assembly 30 may also be removable (e.g., for maintenance operations, such as inspection, replacement, and/or repair), and the locking mechanism 70 may be manually operated in the absence of the remote locking assembly 30. The remote locking assembly 30 may also include a manual lock feature that enables the locking mechanism 70 to be manually operated even in the presence of the remote locking assembly 30 (e.g., while the remote locking assembly 30 is coupled to the bonnet 60), which may provide for an additional or back-up method of operation to drive the locking mechanism 70 (e.g., in case of hydraulic shortage). For example, an end (e.g., outer end, distal from the central bore 56 shown in
As shown, the remote locking assembly 30 includes a motor 84 (e.g., hydraulic motor, pneumatic motor, electric motor) that is coupled to and drives the rotation of the locking mechanism 70 (e.g., via a gear assembly having one or more gears). In particular, the motor 84 may be coupled (e.g., directly, non-rotatably) to a first gear 86 (e.g., spur gear) of the gear assembly (e.g., via an interface between an output shaft of the motor 84 and the first gear 86). The first gear 86 may engage a second gear 88 (e.g., spur gear) of the gear assembly (e.g., via contact between respective teeth of the first gear 86 and the second gear 88). The locking mechanism 70 may be coupled (e.g., directly, non-rotatably) to the second gear 88 of the gear assembly (e.g., via an interface between the locking mechanism 70 and the second gear 88; coaxial). Thus, activation of the motor 84 (e.g., via application of hydraulic pressure in the case of a hydraulic motor) drives rotation of the output shaft of the motor 84, which drives rotation of the first gear 86, which drives rotation of the second gear 88, which drives rotation of the locking mechanism 70. The first gear 86 may have a first diameter, the second gear 88 may have a second diameter, and the first diameter may be less than the second diameter (e.g., to increase torque applied to the locking mechanism 70). It should be appreciated that any of a variety of combinations of gears or similar components may be utilized to transfer torque from the motor 84 to the locking mechanism 70.
As noted above, the rotation of the locking mechanism 70 drives the locking mechanism 70 to move along the axial axis 4 relative to the bonnet 60. For example, the rotation of the locking mechanism 70 in a first direction along the circumferential axis 8 may drive the locking mechanism 70 along the axial axis 4 toward the central bore 56 (
As shown, the remote locking assembly 30 may include certain features that provide a compact structure. For example, in the illustrated embodiment, the motor 84 is positioned between an end (e.g., outer end, distal from the central bore 56 shown in
As shown, the remote locking assembly 30 includes the motor 84 (e.g., hydraulic motor, pneumatic motor, electric motor) that is coupled to and drives the rotation of the locking mechanism 70 (e.g., via a gear assembly having one or more gears). Thus, activation of the motor 84 (e.g., via application of hydraulic pressure in the case of a hydraulic motor) drives rotation of the output shaft of the motor 84, which drives rotation of the gear assembly, which drives rotation of the locking mechanism 70. It should be appreciated that any of a variety of combinations of gears or similar components may be utilized to transfer torque from the motor 84 to the locking mechanism 70.
As noted above, the rotation of the locking mechanism 70 drives the locking mechanism 70 to move along the axial axis 4 relative to the bonnet 60. For example, the rotation of the locking mechanism 70 in a first direction along the circumferential axis 8 may drive the locking mechanism 70 along the axial axis 4 toward the central bore 56 (
As shown, the remote locking assembly 30 may include certain features that provide a compact structure. For example, in the illustrated embodiment, the motor 84 is positioned between an end (e.g., outer end, distal from the central bore 56 shown in
As shown, the remote locking assembly 30 (e.g., the motor 84, the gear assembly) may move with the locking mechanism 70 along the axial axis 4 relative to the bonnet 60. The motor 84 may be offset with respect to fasteners 96 of the bonnet 60 so as to avoid contact with the fasteners 96 as the remote locking assembly 30 moves with the locking mechanism 70 along the axial axis 4 toward the central bore 56 of
As shown, the remote locking assembly 30 includes the motor 84 (e.g., hydraulic motor, pneumatic motor, electric motor) that is coupled to and drives the rotation of the locking mechanism 70 (e.g., via a gear assembly having one or more gears and/or one or more belts). In particular, as best shown in
The locking mechanism 70 may be coupled (e.g., directly, non-rotatably) to the second gear 102 of the gear assembly (e.g., via an interface between the locking mechanism 70 and the second gear 102; coaxial). Thus, activation of the motor 84 (e.g., via application of hydraulic pressure in the case of a hydraulic motor) drives rotation of the output shaft of the motor 84, which indirectly drives rotation of the first gear 100, which drives rotation of the second gear 102, which drives rotation of the locking mechanism 70. The first gear 100 may have a first diameter, the second gear 102 may have a second diameter, and the first diameter may be less than the second diameter (e.g., to increase torque applied to the locking mechanism 70). It should be appreciated that any of a variety of combinations of gears or similar components may be utilized to transfer torque from the motor 84 to the locking mechanism 70.
As noted above, the rotation of the locking mechanism 70 drives the locking mechanism 70 to move along the axial axis 4 relative to the bonnet 60. For example, the rotation of the locking mechanism 70 in a first direction along the circumferential axis 8 may drive the locking mechanism 70 along the axial axis 4 toward the central bore 56 (
As shown, the remote locking assembly 30 may include certain features that provide a compact structure. For example, in the illustrated embodiment, the motor 84 is positioned between an end (e.g., outer end, distal from the central bore 56 shown in
Additionally, an end plate 110 may couple to an end cover 112 to form the gear housing 114 that supports and/or encloses the first gear 100, the second gear 102, and the belt 104. As noted above, the end cover 112 is removed in
As shown, the remote locking assembly 30 includes the motor 84 (e.g., hydraulic motor, pneumatic motor, electric motor) that is coupled to and drives the rotation of the locking mechanism 70 via a connector 122. The connector 122 may be configured to maintain alignment between an output shaft of the motor 84 and the locking mechanism 70 (e.g., to maintain alignment between respective central or rotational axes) during an unlocking operation and a locking operations. For example, the connector 122 may be a universal joint (e.g., U-joint, such as a double U-joint having two U-joints joined by an intermediate shaft) that is configured to maintain the alignment.
Activation of the motor 84 drives rotation of the output shaft of the motor 84, which drives rotation of the connector 122 and the locking mechanism 70 coupled thereto. As noted above, the rotation of the locking mechanism 70 causes the locking mechanism 70 to move along the axial axis 4 relative to the bonnet 60. For example, the rotation of the locking mechanism 70 in a first direction along the circumferential axis 8 may drive the locking mechanism 70 along the axial axis 4 toward the central bore 56 (
A portion of the remote locking assembly 30 (e.g., the motor 84 and the connector 122) may move with the locking mechanism 70 along the axial axis 4 relative to the bonnet 60. As shown, the remote locking assembly 30 may include a carriage system 124 that supports (e.g., slideably supports) the motor 84 and/or the connector 122 as the motor 84 and/or the connector 122 move along the axial axis 4. In particular, the motor 84 (e.g., a motor housing of the motor 84) may be coupled (e.g., fixed, via one or more fasteners) to a bracket 126 that is slideably coupled (e.g., via a sliding interface 128, such as a tongue and groove interface) to a support structure 130 (e.g., frame, rod) of the carriage system 124. The support structure 130 may be coupled (e.g., fixed, via one or more fasteners) to the bonnet 60.
The remote locking assembly 30 may include certain features that provide a compact structure. For example, in the illustrated embodiment, the remote locking assembly 30 is positioned within a lateral extent of the bonnet 60 (e.g., does not extend outwardly from the bonnet 60 along the lateral axis 6) and is also positioned within a vertical extent of the bonnet 60 (e.g., does not extend outwardly from the bonnet 60 along the vertical axis 2). Additionally, the motor 84 is aligned with the locking mechanism 70 (e.g., respective central or rotational axes are aligned; coaxial) and positioned between fasteners 96 of the bonnet 60 so as to avoid contact with the fasteners 96 as the motor 84 moves with the locking mechanism 70 along the axial axis 4 toward the central bore 56 of
In some embodiments, the remote locking assembly 30 may include control components that may be part of the controller 34 of
Advantageously, the remote locking system disclosed herein may be utilized with a BOP, such as a BOP of an offshore system or an on-shore system. Thus, the remote locking system may be configured for use in a subsea environment and/or may have features that enable the remote locking system to be efficiently operated in a subsea environment or another remote environment even while the remote locking system is not physically accessible by an operator (e.g., manually by an operator, an ROV, and/or an AUV). For example, the remote locking assembly may be controlled via a controller in response to inputs at a remote base station (e.g., at a platform at a sea surface) that is physically separate from the remote locking assembly of the remote locking system. It should be appreciated that the remote locking system disclosed herein may be used with any of a variety of types of BOP's, including BOP's that have only a single ram (e.g., that seal the central bore with only the single ram; without an opposed ram). It should also be appreciated that any of the features disclosed above with respect to
While the disclosure may be susceptible to various modifications and alternative forms, specific embodiments have been shown by way of example in the drawings and have been described in detail herein. However, it should be understood that the disclosure is not intended to be limited to the particular forms disclosed. Rather, the disclosure is to cover all modifications, equivalents, and alternatives falling within the spirit and scope of the disclosure as defined by the following appended claims.
The techniques presented and claimed herein are referenced and applied to material objects and concrete examples of a practical nature that demonstrably improve the present technical field and, as such, are not abstract, intangible or purely theoretical. Further, if any claims appended to the end of this specification contain one or more elements designated as “means for [perform]ing [a function] . . . ” or “step for [perform]ing [a function] . . . ”, it is intended that such elements are to be interpreted under 35 U.S.C. 112(f). However, for any claims containing elements designated in any other manner, it is intended that such elements are not to be interpreted under 35 U.S.C. 112(f).
This application claims priority to and the benefit of U.S. Provisional Application No. 62/808,225, entitled “REMOTE LOCKING DEVICE FOR BLOWOUT PREVENTER” filed Feb. 20, 2019. This application is hereby incorporated by reference in its entirety for all purposes.
Number | Date | Country | |
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62808225 | Feb 2019 | US |
Number | Date | Country | |
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Parent | 17432533 | Aug 2021 | US |
Child | 18510775 | US |