Patent Grant
10633966
Hydrocarbon fluids such as natural gas and oil may be obtained from a subterranean geologic formation, referred to as a reservoir, by drilling a well that penetrates the hydrocarbon-bearing geologic formation. In many types of subsea applications, a wellhead is positioned at a sea floor above a wellbore drilled down into the subterranean geologic formation. A subsea tree system is mounted on the wellhead and both the subsea tree system and the wellhead have an internal passage through which various well equipment may be deployed. A seal is positioned between the subsea tree system and the wellhead to ensure a pressure tight seal between the internal passage and the surrounding environment. An isolation sleeve may be used to facilitate pressure testing of the seal.
In general, a system and methodology are provided for facilitating pressure testing of a seal positioned between a wellhead and a subsea tree system. The technique utilizes an isolation sleeve having an upper end inserted into an internal passage of the subsea tree system. The isolation sleeve extends from the subsea tree system for insertion into the corresponding internal wellhead passage when the subsea tree system is landed on the wellhead. The isolation sleeve may comprise a mandrel having an internal mandrel passage as well as a lower seal and an upper seal positioned along an exterior of the mandrel. The isolation sleeve also may comprise a retention member mounted along the exterior of the mandrel. According to an embodiment, the retention member, e.g. a retention nut, may be rotatably mounted about the exterior of the mandrel and comprises external threads or other suitable mechanism for securing the isolation sleeve to the subsea tree system. In some embodiments, the upper end of the isolation sleeve may be constructed in a uniform manner for insertion into a universal profile of the subsea tree system. This approach enables multiple types of isolation sleeves to be constructed with the same upper end, thus reducing costs and time of preparation with respect to various isolation sleeves which may be used with many types of wellheads having differing internal wellhead passage configurations, e.g. different passage diameters.
However, many modifications are possible without materially departing from the teachings of this disclosure. Accordingly, such modifications are intended to be included within the scope of this disclosure as defined in the claims.
Certain embodiments of the disclosure will hereafter be described with reference to the accompanying drawings, wherein like reference numerals denote like elements. It should be understood, however, that the accompanying figures illustrate the various implementations described herein and are not meant to limit the scope of various technologies described herein, and:
In the following description, numerous details are set forth to provide an understanding of some embodiments of the present disclosure. However, it will be understood by those of ordinary skill in the art that the system and/or methodology may be practiced without these details and that numerous variations or modifications from the described embodiments may be possible.
The present disclosure generally relates to a system and methodology for facilitating pressure testing of a seal positioned between a wellhead and a subsea tree system. The technique utilizes an isolation sleeve having an upper end inserted into an internal passage of the subsea tree system. By way of example, the subsea tree system may comprise a Christmas tree, e.g. a vertical Christmas tree, or a tubing head spool into which the upper end of the isolation sleeve is inserted.
The isolation sleeve extends from the subsea tree system for insertion into the corresponding internal wellhead passage when the subsea tree system is landed on the wellhead. The isolation sleeve may comprise a sleeve body referred to as a mandrel which has an internal mandrel passage. Additionally, the isolation sleeve comprises a lower seal and an upper seal positioned along an exterior of the mandrel.
The isolation sleeve also may comprise a retention member mounted along the exterior of the mandrel. According to an embodiment, the retention member, e.g. a retention nut, is rotatably mounted about the exterior of the mandrel and comprises external threads for securing the isolation sleeve to the subsea tree system. The retention member may be rotated independently of the mandrel and upper/lower seals to secure the isolation sleeve to the subsea tree system.
In some embodiments, the upper end of the isolation sleeve may be constructed in a uniform manner for insertion into a universal profile of the subsea tree system. This approach enables multiple types of isolation sleeves to be constructed with the same upper end profile, thus reducing costs and time of preparation. The lower ends of the isolation sleeves may be designed for use with many types of wellheads having differing internal wellhead passage configurations/diameters. In other words, isolation sleeves for use with many different types of wellheads, e.g. various third-party wellheads, may be similarly constructed with a universal upper profile for reception in the universal profile of the corresponding subsea tree systems.
According to an embodiment, the retention nut and mandrel are constructed to allow external installation and activation of the retention nut whether the upper seal or lower seal has a larger diameter than the other. This configuration enables the external installation and activation of the retention nut regardless of whether the lower section of the isolation sleeve seals against a larger bore wellhead, smaller bore wellhead, or against another wellhead component such as a third position casing hanger.
Additionally, the isolation sleeve may be constructed with a single piece mandrel having leak paths along the isolation sleeve limited to two positions, i.e upper seal and lower seal, along the exterior of the mandrel. The retention nut or other retention member may be rotated independently of the upper and lower isolation sleeve seals, and the rotation may be performed via a single set of externally-installed assembly tooling. Furthermore, the configuration of the isolation sleeve enables removal, installation, or replacement of the seal between the subsea tree system and the wellhead independently of the isolation sleeve. In other words, the isolation sleeve does not interfere with the removal/installation/replacement processes.
Depending on the features utilized in a particular isolation sleeve, embodiments described herein may provide various benefits. By way of example, the use of a universal profile allows the bottom of each subsea tree system to be uniformly machined with the universal profile for receipt of various types of isolation sleeves having the corresponding uniform upper sleeve profile. With the universal profile, the upper seal used on the isolation sleeve may be preselected for use in the universal profile and this can eliminate the time and expense associated with qualifying a new seal size and type.
Furthermore, constructing the isolation sleeve with a single piece mandrel having a single, continuous structure limits the potential leak paths to a total of three leak paths, i.e. two potential leak paths at the upper and lower seals of the isolation sleeve and one potential leak path at the seal between the wellhead and subsea tree system. Such a single, unitary structure avoids construction of the isolation sleeve with a multi piece mandrel which would effectively establish additional potential leak paths. The use of a universal profile also enables construction of subsea tree systems with a predefined and minimized space allocation for the isolation sleeve. Without the universal profile, additional space would be provided at the bottom of the subsea tree system to accommodate different types of isolation sleeves having different upper profiles. Such oversized systems incur additional costs as well as additional weights and heights.
Referring generally to
Referring generally to
According to the illustrated embodiment, the isolation sleeve 30 comprises a mandrel 40 having an internal mandrel passage 42. The isolation sleeve 30 also comprises a lower seal 44 and an upper seal 46 which are both positioned along an exterior surface 48 of mandrel 40. The lower seal 44 is positioned for sealing engagement with the wellhead 22 and the upper seal 46 is positioned for sealing engagement with the subsea tree system 26. According to the embodiment illustrated, mandrel 40 is formed as a single, continuous structure. In other words, the mandrel 40 may be constructed as a unitary piece instead of joining a plurality of pieces that would be attached and sealed together to form the mandrel—thus creating additional potential leak paths.
Additionally, the isolation sleeve 30 comprises a retention member 50 which may be rotatably mounted along the exterior 48 of mandrel 40. By way of example, the retention member 50 may be located between the upper seal 46 and the lower seal 44. The retention member 50 may have various forms such as a ring having external threads 52 oriented for threaded engagement with corresponding threads 54 located along the internal passage 32 of subsea tree system 26. However, the retention member 50 may be secured via retention rings or other retention mechanisms instead of threads 52.
In the example illustrated, the retention member 50 is in the form of a retention nut. The outer diameter of the mandrel 40 is selected to enable external rotation of the retention member 50 via a single set of externally-installed assembly tooling. Additionally, the retention member 50, e.g. retention nut, may be rotatable independently of mandrel 40 and the lower and upper seals 44, 46.
After assembly of isolation sleeve 30, the isolation sleeve 30 may be inserted into internal passage 32 and retention member 50 may be rotated to secure its engagement with subsea tree system 26 via threads 52, 54. A retention mechanism 55, e.g. a split metal O-ring, may be positioned between mandrel 40 and retention member 50 to prevent backing off of threads 52 and 54. In some embodiments, retention mechanism 55 may be located between retention member 50 and subsea tree system 26 along internal passage 32.
According to an embodiment, the retention member/nut 50 is initially slid over an upper end 56 of mandrel 40 but its travel along the upper end 56 is limited by an abutment 58 formed along mandrel 40. After sliding the retention member 50 onto mandrel 40, a load ring 60, e.g. a split load ring, is secured along the exterior 48 of mandrel 40 and serves as another abutment. Thus, the retention member 50 is trapped between abutment 58 and the abutment provided by load ring 60.
In some embodiments, a retainer ring 62 may be positioned on mandrel 40 to further support and retain load ring 60 during loading. By way of example, the retainer ring 62 may be free-floating but limited in movement by load ring 60 below and upper seal 46 above. The retainer ring 62 also could be secured to mandrel 40 via at least one set screw or other suitable fastening mechanism. It should be noted substantial loads may be applied against the retention member 50 and load ring 60 during pressure testing of seal 28, particularly when lower seal 44 and upper seal 46 have different diameters.
Once the load ring 60 is positioned and secured in place, the upper seal 46 may be positioned above the load ring 60 and secured in place via an upper seal retainer 64, e.g. a seal retainer nut, which may be threaded onto mandrel 40. A set screw 65 or other retention member may be used to secure the upper seal retainer 64 in place. Similarly, the lower seal 44 may be slid over a lower end 66 of the mandrel 40 proximate a seal abutment 68. The lower seal 44 may then be secured via a lower seal retainer 70, e.g. a seal retainer nut, which may be threaded onto mandrel 40. A corresponding set screw 72 or other retention member may be used to secure the lower seal retainer 70 in place. After securing the isolation sleeve 30 between the subsea tree system 26 and wellhead 22, the seal 28 may be pressure tested by supplying pressure test region 38 with pressurized fluid via a suitable pressure passage 74 through subsea tree system 26. The pressure passage 74 may be placed in communication with pressure test region 38 at, for example, a location below retention member 50 or via a pressure bypass conduit in retention member 50.
In the embodiment illustrated in
Referring generally to
Referring generally to
The isolation sleeve 30 may be secured in subsea tree system 26 via threaded engagement of retention member 50. For example, retention member 50 may be independently rotated about mandrel 40 to engage threads 52 with threads 54. The retention mechanism 55, e.g. a split metal O-ring, may be positioned between mandrel 40 and retention member 50 to prevent backing off of threads 52 and 54.
During assembly of the isolation sleeve 30 illustrated in
In this example, the load ring 84 may be positioned so it will be proximate lower seal 44 and below retention member 50. The load ring 84 may serve as a seal abutment for lower seal 44. Additionally, the retention member 50 is trapped between upper abutment 82 and the lower abutment provided by load ring 84. In some embodiments, a retainer ring 86 may be mounted on mandrel 40 to further support and retain load ring 84. By way of example, the retainer ring 86 may be free-floating but limited in movement by load ring 84 above and lower seal 44 below. The retainer ring 86 also could be secured to mandrel 40 via at least one set screw or other suitable fastening mechanism.
Once the load ring 84 is positioned and secured in place, the lower seal 44 may be slid over lower end 66 and located at its operational position below the load ring 84. The lower seal 44 may be secured in place via lower seal retainer 70, e.g. a seal retainer nut, which may be threaded onto mandrel 40. The set screw 72 or other retention member may be used to secure the lower seal retainer 70 in place.
Similarly, the upper seal 46 may be slid over the upper end 56 of mandrel 40 until it bottoms out on a shoulder 88 of mandrel 40. The upper seal 46 may then be secured via upper seal retainer 64, e.g. a seal retainer nut, which may be threaded onto mandrel 40. The corresponding set screw 65 or other retention member may be used to secure the upper seal retainer 64 in place. After securing the isolation sleeve 30 between the subsea tree system 26 and wellhead 22, the seal 28 may similarly be pressure tested by supplying pressure test region 38 with pressurized fluid via the pressure passage 74 through subsea tree system 26.
In the embodiment illustrated in
Referring generally to
Accordingly, embodiments of isolation sleeve 30 have various types of mandrels. Each mandrel 40 serves as an isolation sleeve body to which lower seal 44 and upper seal 46 may be mounted to seal and isolate the pressure test region 38 for pressure testing seal 28. The retention member 50 may be rotated independently of the mandrel 40 and isolation sleeve seals 44, 46 to secure and retain the isolation sleeve 30 in the subsea tree system 26. The retention member 50 also may be installed externally of the mandrel 40 regardless of the wellhead geometry.
Various split rings and other retainer rings may be used to support components of the isolation sleeve 30 and to provide a load path for system loads. The isolation sleeve 30 also may be constructed with a universal profile at its upper end for engagement with a corresponding universal profile of the subsea tree system 26. Other and/or additional components may be used with isolation sleeve 30 to facilitate pressure testing operations in a variety of environments and with many types of subsea installations.
For example, the isolation sleeve 30 may be used with many types of subsea tree systems 26 and may be secured within, for example, a tubing head spool or a Christmas tree. Additionally, the isolation sleeve 30 may comprise various types and sizes of seals, load rings, seal retainers, and other components to facilitate pressure testing operations. The retention member 50 also may have a variety of forms with various thread types for engaging the interior of subsea tree system 26. Depending on the arrangement of components, the retention member 50 may be positioned on the mandrel 40 from the top end or from the bottom end. Various abutments may be used to contain the retention member 50 and to provide load paths for loading resulting from pressure differentials or other types of loading experienced by the isolation sleeve 30.
Although a few embodiments of the disclosure have been described in detail above, those of ordinary skill in the art will readily appreciate that many modifications are possible without materially departing from the teachings of this disclosure. Accordingly, such modifications are intended to be included within the scope of this disclosure as defined in the claims.
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