The present disclosure relates generally to subsea well systems and methods and, more particularly, to subsea well systems and methods for production and intervention on high pressure high temperature (HPHT) wells.
Offshore oil and gas operations typically involve drilling a wellbore through a subsea formation and disposing a wellhead at the upper end of the well (e.g., at the mudline). A string of casing can be landed in the wellhead, and a tubing spool is generally connected to the top of the wellhead. A tubing hanger lands in the tubing spool, and the tubing hanger suspends a production tubing string through the wellhead and tubing spool into the casing string. A conventional production tree can be connected to the top of the tubing spool to route product from the tubing hanger (and production tubing) toward a production riser. The production riser generally includes a series of riser pipes connected end to end to connect the subsea production components to, for example, a topside production facility. Such subsea systems are often used to extract production fluids from subsea reservoirs.
Recently, the oil and gas industry has begun to see increased activity and interest in developing a wider variety of offshore reservoirs. Specifically, there is an increased interest in developing high pressure high temperature (HPHT) subsea reservoirs. The term HPHT refers to wells that have mudline pressures in excess of 15,000 psi, temperatures in excess of 350 degrees F., or both. In an effort to develop such HPHT reservoirs, it is desirable to provide new methods and equipment to safely drill, complete, produce, and intervene on HPHT wells over the economic life of the well.
For a more complete understanding of the present disclosure and its features and advantages, reference is now made to the following description, taken in conjunction with the accompanying drawings, in which:
Illustrative embodiments of the present disclosure are described in detail herein. In the interest of clarity, not all features of an actual implementation are described in this specification. It will of course be appreciated that in the development of any such actual embodiment, numerous implementation specific decisions must be made to achieve developers' specific goals, such as compliance with system related and business related constraints, which will vary from one implementation to another. Moreover, it will be appreciated that such a development effort might be complex and time consuming, but would nevertheless be a routine undertaking for those of ordinary skill in the art having the benefit of the present disclosure. Furthermore, in no way should the following examples be read to limit, or define, the scope of the disclosure.
Certain embodiments according to the present disclosure may be directed to a subsea system and an associated method for completion, production, and intervention on high pressure and/or high temperature (HPHT) subsea wells. The system may be utilized for transporting oil, gas, and other fluids from a subsea well to an offshore production facility.
Most offshore wells that are currently being produced operate at pressures less than and up to approximately 10,000 psi. However, it is now desirable to produce hydrocarbons from subsea HPHT wells that operate within pressure ranges of up to approximately 15,000 psi, up to approximately 20,000 psi, or higher pressures. This would enable the development of subsea reservoirs that are not currently accessible. Operating in such high pressure and/or high temperature environments may involve the use of new and advanced technology, enhanced seals, new types of materials (e.g., materials with higher strengths and properties that do not degrade significantly at high temperatures, pressures, and various drilling and production fluids), and other improvements to increase the pressure rating of various subsea system components.
The disclosed embodiments provide a full top-to-bottom subsea system that can be used to drill, complete, produce, and perform interventions on HPHT subsea wells. The disclosed systems and methods involve the use of at least one controlled multiple barrier system, such as a high integrity pipeline protection system (HIPPS), incorporated into the subsea system to divide the system into two sections. The sections on either side of the disclosed barrier may be rated for different pressures, temperatures and/or flow rates. For example, the first section (upstream of the barrier) is rated for operating at pressures/temperatures/flow rates up to a first (higher) threshold. At least a portion of the second section (downstream of the barrier) is rated for operating at pressures/temperatures/flow rates up to a second (lower) threshold. The disclosed subsea production system methodology, which uses the HIPPS or other barrier to divide the system components between two pressure ratings, may allow for enhanced development of HPHT reservoirs.
Turning now to the drawings,
In the illustrated embodiment, the flowline system 22 may include a fortified well jumper 28, a flowline 30 with opposing flowline pipeline end terminations/manifolds (PLETs/PLEMs) 32 at opposite ends thereof, a riser PLET 34, and a flowline jumper 36 for coupling the flowline PLET/PLEM 32 to the riser PLET 34. The term “fortified well jumper” refers to a well jumper that is fully rated for the higher pressures/temperatures/flow rates expected from downhole (e.g., pressures up to 15,000 psi, 20,000 psi, or more). The various PLETs described herein may generally function as end points for associated flowlines. It should be noted that other numbers and relative arrangements of such flowline components, end terminals, manifolds, and jumpers may be used in other embodiments of the flowline system 22. For example, in some embodiments, a flowline pipeline end manifold (PLEM) may be substituted for one or both of the illustrated flowline PLETs 32, enabling multiple production wells to feed into the same production facility 26 via the riser 24.
The system 10 of
In some embodiments, the barrier 38 may include a high integrity pipeline protection system (HIPPS). The HIPPS module may be a skid-mounted system that features a series of chokes, sensors, and valves between the wellhead 12 and the flowline system 22, and a control module. The control module is used to control the pressure of production fluids and other fluids let through the barrier in a particular direction, and to isolate an upstream pressure source from the downstream facilities (e.g., 26). In the illustrated embodiment, the barrier 38 may be provided as a separate skid unit with a control module for keeping the pressure of production fluids below a desired threshold as the production fluid moves downstream from the reservoir 14 to the topside production facility 26. As described below, other embodiments of the barrier 38 may feature valves, chokes, and/or control components that are spread throughout the system 10, or integrated into a more upstream component of the system 10.
The barrier 38, and all equipment upstream of the barrier 38, may be rated for a maximum pressure, temperature, or flow rate that is equal to or greater than the maximum pressure, temperature, or flow rate of the HPHT reservoir 14. This maximum pressure may include the highest expected reservoir shut-in pressure plus an additional margin, which may be for chemical injection into the subsea production system 10 and subsea wellbore or for operation of the surface-controlled subsurface safety valve (SCSSV). The subsea system components that are rated for the higher pressure/temperature/flow rate are indicated by dashed lines in
Downstream of the barrier 38, one or more pieces of wellbore equipment may be rated for a maximum pressure, temperature, or flow rate that is less than that of the upstream (higher rated) system components. This lower pressure/temperature/flow rating is indicated by solid (not dashed) lines in the illustrated embodiment. In some embodiments, these components may be rated for pressure of up to approximately 7,000 psi to 10,000 psi. In other embodiments, these components may be rated for pressures of up to approximately 15,000 psi. The barrier 38 may be used to protect this downstream equipment from the relatively higher fluid pressures experienced upstream, thereby allowing more technically and commercially feasible flowline (22) and riser (24) equipment to be utilized. For example, the riser 24 and certain flowline equipment may be constructed from cheaper materials, may utilize less complex seals, and may require less costly development than the higher rated upstream components.
Having generally described the components that make up the disclosed HPHT subsea system 10, a method describing various completion, production, and intervention processes associated with the subsea system 10 will be provided. In association with the steps of this method,
In addition, the subsea system 10 may include a tubing hanger 70. As shown, the tubing hanger 70 is fluidly coupled to the bore 72 of the tree 18. In the illustrated embodiment, an isolation sleeve 74 may seal the tree 18 to the tubing hanger 70. A tubing hanger plug 76 may be removably placed within the tubing hanger 70 at one or more times throughout the completion and workover processes described below. The tubing hanger 70 may be landed in a shoulder in bore 78 of the THS 16 and sealed to the THS 16, as shown. The tubing hanger 70 may suspend a tubing string 80 into and through the wellhead 12. The wellhead 12, likewise, may suspend one or more casing strings (e.g., inner casing string 82A and outer casing string 82B) from corresponding hangers (e.g., hanger 84A and hanger 84B). As illustrated, a surface controlled subsurface safety valve (SCSSV) 85 may be disposed within a portion of the tubing string 80 extending from the wellhead 12.
Referring now to the components shown in both
Once the BOP is in place, one or more casing strings 82 may be lowered through the BOP and the high pressure wellhead 12, such that the casing strings 82 extend into the wellbore. As mentioned above, the casing strings 82 may be landed in the wellhead 12 via corresponding hangers 84 that are disposed in a sealing engagement within a bore 86 of the wellhead 12. Once the casing strings 82 are landed, the method may include retrieving the BOP and installing the THS 16 onto the top of the wellhead 12. After positioning and sealing the THS 16 onto the wellhead 12, the BOP may be run and connected to the top of the THS 16.
At this point, the method may include connecting the tubing hanger 70 (and associated tubing 80) through a BOP completion riser system, which includes a subsea test tree (SSTT) and landing string. The BOP completion riser system may be a specialized tool that can be lowered into the THS 16 and used to deploy, actuate, and/or remove one or more pieces of equipment. The method may further include running the tubing hanger 70 (and associated tubing 80) through the BOP completion riser system and landing the tubing hanger 70 in a sealing engagement within the bore 78 of the THS 16. In some embodiments, the method may include installing the plug 76 within the tubing hanger 70 via a wireline that is lowered from the surface through the BOP completion riser system. The plug 76 may function to seal the inner bore of the tubing hanger 76. Then the BOP completion riser system may be disengaged from the landed tubing hanger 70 and retrieved to the surface. The BOP may then be removed from the THS 16 and retrieved to the surface.
The method may further include landing the production tree 18, onto the THS 16 and making up the completion riser system onto the internal profile of the production tree 18 after the tree 18 has been landed on the THS 16. The tree 18 may be sealed onto the THS 16 and against the tubing hanger 70 via the isolation sleeve 74. The method may include retrieving the plug 76 from the tubing hanger 70 via the wireline. After retrieving the wireline plug 76, the method may include disconnecting the BOP and completion riser system from the tree 18 and retrieving them back to the surface. The method may then include installing a tree cap, which is not shown, onto the top of the production tree 18. Once assembled in this manner, the tree 18 may function to direct production fluids in a controlled manner from the wellbore.
Upon constructing the stack of the wellhead 12, THS 16, and tree 18 as described above, the method may include connecting the tree 18 to the barrier 38, for example a high-integrity pressure protection system (HIPPS) module, via the well jumper 20. Then the barrier 38 may be connected to the flowline 30 (or a gather manifold 32) via the fortified jumper 28. The term “fortified jumper” refers to a well jumper that is rated for the higher pressures expected from downhole (e.g., up to 15,000 psi, 20,000 psi, or more). The flowline 30 and/or manifold 32 may then be connected to the riser 24 via the flowline jumper 36, for example. The riser 24 may be connected to the floating production facility 26, as shown.
One or more subsea control components and/or umbilicals from the topsides facility 26 may be installed and connected to the subsea production equipment. The method then includes commissioning the subsea facility, and starting up production to flow back the well to the production facilities 26 for regulatory and data gathering purposes. Upon completion of the flowback, the subsea production system 10 may be controlled to commence normal production operations.
Over the life of the well, the completion riser system described above or a completion workover riser (CWOR) system may be used to lower equipment into the tree 18, THS 16, wellhead 12, or other components of the subsea system 10 to perform interventions as needed. In some embodiments, it may be possible to utilize existing intervention equipment that is rated for only up to 15,000 psi as the reservoir pressure declines throughout the productive life of the well.
It should be noted that the wellhead 12 used in the disclosed subsea system may be rated for maximum pressures beyond 15,000 psi. To that end, it may be desirable for the wellhead 12 to be sized larger than existing wellheads that are rated for lower pressures. For example, in the disclosed systems the wellhead 12 may include a mandrel with an outer diameter of approximately 35 inches. The larger mandrel diameter of the wellhead 12 used in the system 10 may enable fluid to flow through the wellhead 12 at greater pressures than would be available using smaller conventional wellheads. Additionally, the larger mandrel diameter of the wellhead 12 is capable of supporting larger external static loads (bending, tension, compression, shear, etc.) and more severe fatigue load spectrums that are generated in HPHT applications due to larger size BOPs, taller stacks, new rigs, dual gradient offsets, and so forth. In some embodiments, the wellhead 12 may feature an 18¾ inch nominal bore diameter. In such systems 10, the production components may be sized such that a nominal production bore of 3, 4, or 5 inches is provided, for example, in the tubing hanger 70, tree 18, and completion riser system/CWOR. However, other embodiments of the subsea system 10 may feature other sizes of wellheads 12 that are still rated for 20,000 psi or more.
The method described above represents one possible method for performing well drilling, completion, production, and intervention operations. Other methods may be utilized that eliminate, replace, or alter one or more of the steps described above, based on the physical layout of the subsea system 10. Some examples of such other embodiments of the system 10 will now be described.
In some embodiments, the subsea system 10 may include an additional fortified zone downstream of the HIPPS or other barrier 38. The term “fortified” refers to these system components being rated for relatively higher pressures (e.g., up to approximately 15,000 psi or 20,000 psi). The fortified zone may include, for example, a fully rated jumper (28), manifold (32), flowline (30), or combination thereof. This may provide a higher rated section of the flowline system 22 to allow for adequate response and closure time of the pressure barrier valve(s) of barrier 38, in the event of a downstream pipeline blockage or hydrate formation. The fortified zone length may be determined by analyzing the dynamic pressure/temperature response within the flowline during a high pressure/temperature event and sizing the fortified length to provide an adequate response time for the barrier 38 to activate (close) before the high pressure/temperature fluid reaches the lower rated downstream pipeline.
The valve 110 may be installed in its position at or below the tubing hanger 70 prior to the tubing hanger assembly being brought to the well site. In some embodiments, the valve 110 may include a threaded portion designed to thread directly into the bottom of the tubing hanger 70. In other embodiments, the valve 110 may be threaded onto or integrated with a portion of the tubing string 80 extending beneath the tubing hanger 70. In embodiments where the valve 110 is disposed below the tubing hanger 70, the valve 110 may be designed similar to the production tubing SCSSV 85. In still other embodiments, the valve 110 may be integrated directly into the tubing hanger 70. That is, the valve 110 may be built into the tubing hanger 70 during the initial construction of the tubing hanger 70. As shown, the production tree 18 may also be equipped with a valve 112 that provides an additional barrier above the swab in the production bore.
The pre-installed valve 110 may be particularly suitable for use during the construction and workover phases of the subsea system 10. First, the valve 110 may be pre-set to the desired open or closed position as the tubing hanger 70 is run into and landed in the THS 16. The valve 110 can then be actuated open or closed remotely, without requiring a designated wireline trip. That is, a topsides operator can simply select a control command to actuate the pre-installed valve 110, instead of installing a new plug (e.g., 76 of
In addition to eliminating certain installation/retrieval trips, the valve 110 may function as a redundant safety valve at certain times during the construction of the system 10. Once the valve 110 is installed along with the tubing hanger 70, it may operate similar to a back-up SCSSV. This back-up valve function may be particularly desirable during the workover phase before the tree 18 and/or the barrier 38 are attached to the system components. At this time, the valve 110 may provide some risk reduction prior to and while the other pressure/flow control components (e.g., tree 18, barrier 38) are being installed.
For this scenario, a fully rated flowline system 22 and riser system 24 may be utilized downstream of the subsea production tree 18. That is, the equipment downstream of the production tree 18 may be rated for a pressure that is equal to the maximum reservoir pressure (i.e., less than 15,000 psi). This effectively eliminates the need for the HIPPS barrier valves described above. The wellhead 12, THS 16, and tree 18, however, may be rated at a pressure equal to or greater than the reservoir pressure plus an expected well operating pressure margin (i.e., greater than 15,000 psi). This higher pressure rating is indicated in
Overpressure protection of the lower rated downstream equipment (22, 24) due to chemical injection into the wellbore may be provided via a Safety Instrumented System (SIS) 130 located on the topsides facility 26, used in conjunction with subsea valve interlocks provided via a subsea control system (not shown). The subsea valve interlocks may include a plurality of valves disposed along flowlines about the wellhead 12, tree 16, or other subsea production equipment. The Safety Instrumented System 130 may control these valves together to maintain a desired subsea operational state (i.e., maintaining a lower pressure downstream of the wellhead 12). In this manner, the subsea valve interlocks may function as the pressure barrier in this system 10.
Still other arrangements of the subsea system 10 may provide a desired pressure barrier between higher rated and lower rated subsea equipment for use in production of HPHT wells. For example, some embodiments of the subsea system 10 may feature a looped flowline system 140 (as shown in
In other embodiments, the subsea system 10 may feature a pressure barrier 38 disposed within the flow loop of the subsea production tree 18 (as shown in
In some embodiments, the pressure barrier 38 may include a common design of interfacing hardware that can be used to couple the pressure barrier 38 to different components of the subsea system. For example, the same design for the pressure barrier 38 may be used to interface with equipment including the production tree 18 (e.g.,
As shown in
Although the present disclosure and its advantages have been described in detail, it should be understood that various changes, substitutions and alterations can be made herein without departing from the spirit and scope of the disclosure as defined by the following claims.
The present application claims priority to U.S. provisional application Ser. No. 62/233,027, entitled “Subsea System and Method for High Pressure High Temperature Wells”, filed on Sep. 25, 2015.
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Number | Date | Country | |
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20170089182 A1 | Mar 2017 | US |
Number | Date | Country | |
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62233027 | Sep 2015 | US |