Submersible systems are utilized in a variety of applications, such as subsea applications. For example, pressure and flow controlling devices, such as subsea test trees, facilitate the production of hydrocarbon-based fluids. Other pressure and/or flow control equipment, e.g. horizontal Christmas trees, also are used in subsea applications for the production of desired fluids.
In many subsea applications, there is an increasing demand for smaller trees and wellheads with larger bores and valves to control the flow of wellbore fluids. However, the drift diameters of pressure controlling equipment, such as subsea test trees or horizontal Christmas trees, are limited to certain sizes and/or pressure ratings. This is necessary to accommodate conventional valve closure devices and their corresponding actuator mechanisms which are permanently packaged together.
Additionally, removal of the valve or actuator during servicing or replacement requires disassembly of components of the pressure housing. Generally, such disassembly results in the breaking of “pressure tested” barriers and the loss of pressure integrity within the system. Loss of pressure integrity can result in the outflow of production fluid into the surrounding environment.
With horizontal Christmas trees, for example, if the valve or its actuator fail, it may become necessary to decomplete and seal off the well to maintain pressure integrity while the entire horizontal Christmas tree is recovered for repair. Such an operation is extremely expensive due to both the cost of recovering the Christmas tree as well as the production downtime when the well is sealed.
In one embodiment of the present invention, a submersible system, such as a subsea system, is designed for the control of pressure and fluid flow in the production of such fluid. The technique utilizes an internal device, such as a valve, controlled by an external actuator. The actuator interacts with the internal device, e.g. valve, via an actuator stem. Within the system, a seal region is disposed for selective engagement with the stem to ensure maintenance of internal pressure integrity. For example, if the internal device comprises a flow control valve, the valve may be removed for servicing while the stem seals against the seal region to maintain internal pressure integrity.
Certain exemplary embodiments of the invention will hereafter be described with reference to the accompanying drawings, wherein like reference numerals denote like elements, and:
Referring generally to
Submersible system 20 further comprises an internal component 28, an external actuator 30, a stem 32 and a seal region 34. In the exemplary embodiment illustrated, external actuator 30 is mounted to pressure housing 24 by a bonnet 36. Bonnet 36 may be mounted to the exterior of pressure housing 24 by an appropriate fastening mechanism 38, e.g., bolts 40. In this example, bolts 40 extend through a bonnet flange 42 and are threadably received in pressure housing 24.
Internal component 28 may comprise a variety of actuatable components. However, in the embodiment illustrated, internal component 28 comprises a valve assembly having a valve 44 and a valve closure mechanism 46. Actuator stem 32 cooperates with valve closure mechanism 46 to selectively open and close valve 44. In a variety of subsea applications, valve 44 comprises a gate valve. However, depending on the application, valve 44 also may comprise a ball valve or other type of actuatable valve.
As illustrated best in
Control over valve 44 is provided by external actuator 30, which is mounted externally to hollow interior 26 to, for example, maximize flow area along the internal fluid flow path defined by hollow interior 26. A variety of actuator types are available depending on the specific application, e.g., fail-close actuator or fail-open actuator; function of internal component 28, e.g. gate valve, ball valve, etc.; and mode of actuation, e.g. hydraulic, electrical, etc. In the embodiment illustrated, external actuator 30 is a hydraulically powered actuator having an internal piston 48 slidably mounted within an actuator housing 50.
Piston 48 is coupled to stem 32 via an appropriate linkage 56. By introducing hydraulic fluid into a fluid chamber 58 under pressure, piston 48 is moved towards pressure housing 24 which, in turn, moves stem 32 in a linear direction to actuate valve 44 between the closed and open positions. When the pressure of the hydraulic fluid is decreased, a spring member 59 forces piston 48 and stem 32 in an opposite direction. If the hydraulic pressure is sufficiently decreased, stem 32 is fully retracted from engagement with internal component 28, e.g. valve 44, to a sealed position, as illustrated in FIG. 3. Actuator 30 may also comprise a hydraulic override rod 60 engaged with piston 48 and slidably mounted in a sleeve 61. Sleeve 61 allows access to override rod 60 by, for example, a remotely operated vehicle in the event of hydraulic failure.
In the embodiment illustrated, stem 32 may be fully removed from internal fluid flow path 26 to permit removal of the internal component 28. It should be noted that stem 32 may be moved from an engaged position, as illustrated in
When fully retracted, stem 32 is in engagement with seal region 34 to prevent the outflow of fluid from internal fluid flow path 26 to the environment surrounding flow control structure 22. As illustrated, stem 32 is slidably mounted within a passage 62 extending through bonnet 36. In this embodiment, seal region 34 is formed by a backseat 64. Stem 32 comprises a shoulder 66 positioned and shaped for mating engagement with backseat 64 when stem 32 is moved to the fully retracted position.
When shoulder 66 engages backseat 64, a seal is formed sufficient to maintain internal pressure integrity within pressure housing 24. In other words, fluid within the hollow interior 26 that forms the internal fluid flow path cannot escape proximate bonnet 36 and external actuator 30. Additionally, the cooperation of backseat 64 and shoulder 66 prevents stem 32 from being forced through bonnet 36.
Thus, if valve 44 or other internal components 28 are removed, as illustrated in
When the components are removed, the relatively greater internal pressure within pressure housing 24, as indicated by arrows 68 in
The ability to maintain pressure integrity can be utilized in a variety of subsea systems. For example, in
In the example of
The horizontal Christmas tree may comprise other components, such as a tubing hanger 90 having internal flow passages 92, and a master production valve 94. Additionally, a variety of other features may be utilized with or incorporated into the horizontal Christmas tree 70. However, the design of internal valves 78, 80, external actuators 82, 84 and seal regions 34, allows removal of the valves and/or actuators without compromising the pressure integrity within flow control structure 72. Thus, one or more of the valves, actuators and tubing hanger may be removed, and the horizontal Christmas tree 70 can be left in place on the wellhead without the need to decomplete and seal the well.
In another embodiment of the present invention, pressure integrity is maintained in a subsea test tree system 96. In this exemplary system, a flow control structure 98 is coupled to a Christmas tree 100, such as a horizontal Christmas tree. Christmas tree 100 is coupled to a master production valve 102, and a horizontal Christmas tree tubing hanger 104 is deployed therein. Disposed above Christmas tree 100, flow control structure 98 comprises a pressure housing 106 having a hollow interior that forms an internal fluid flow path 108. A tubing hanger running tool 110 is disposed within pressure housing 106 along with one or more internal valves 112 each actuated by an external actuator 114. In the embodiment illustrated, two internal valves 112 are actuated by corresponding external actuators 114 via actuator stems 116. Subsea system 96 also may comprise other components, such as a blowout preventer 116 and an umbilical-less radial penetrator port 118.
As discussed with respect to the embodiments described above, the actuators 114 and/or valves 112 may be removed without compromising the pressure integrity within flow control structure 98. Each actuator stem 116 is moved to a retracted position via the corresponding actuator and/or the internal pressure within pressure housing 106 to form a seal at the corresponding seal region 34. As described with reference to
It should be understood that the foregoing description is of exemplary embodiments of this invention, and that the invention is not limited to the specific forms shown. For example, a variety of actuators may be used to actuate gate valves, ball valves, other types of valves or other internal components; the technique for maintaining pressure integrity may be utilized in a variety of submersible, e.g. subsea, systems; the number of valves and actuators used in a given system may vary according to the specific application; the internal valves may be actuated by linear, rotational or other motion of the actuator stem; and various other features may be incorporated into the system. These and other modifications may be made in the design and arrangement of the elements without departing from the scope of the invention as expressed in the appended claims.
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Number | Date | Country | |
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20040118567 A1 | Jun 2004 | US |