Rigless abandonment system

A rigless abandonment system including a surface vessel having an attached lifting device and a moonpool. The system further includes a cutting module configured to connect to a subsea wellhead, the cutting module having a wellhead connector having an actuatable lock and release mechanism, a motor assembly, and a cutter. An umbilical line connects the cutting module to the surface vessel, wherein the lifting device is used to raise and lower the cutting module connected to the surface vessel through the moonpool. A method for performing rigless casing cutting and wellhead removal operations, the method includes positioning a surface vessel above a subsea wellhead, where the surface vessel has a moonpool and a lifting device. The method further includes providing a cutting module, and deploying the cutting module through the moonpool, wherein the cutting module is connected to the surface vessel by an umbilical line.

BACKGROUND OF THE INVENTION

1. Field of the Invention

Embodiments disclosed herein relate generally to the removal of subsea wellhead assemblies and, more particularly, to the cutting of well casing below a wellhead to enable removal of the wellhead. Specific embodiments relate to cutting the casing and removing the wellhead in a single trip.

2. Description of the Related Art

When an oil or gas well is to be abandoned, government regulations usually require removal of the wellhead. The usual procedure includes steps such as plugging the well with a suitable cement composition, testing the integrity of the plug, and then removing the wellhead assembly. On land, the wellhead assembly can be removed by standard construction techniques and in general, the casing immediately below the wellhead will be cut off several meters below ground level to allow reinstatement of the well site. However, this technique cannot satisfactorily be applied to subsea wells as casings often need to be cut underwater, in situ.

In the case of a subsea well, abandonment usually entails plugging the well bore with cement and then detonating an explosive charge within the well casing slightly below the level of the wellhead in order to cut the casing at that point and free the wellhead assembly for removal. This technique is unsatisfactory because portions of the wellhead removed after explosive cutting can become damaged and not suitable for re-use.

When the use of explosives is not available or desired, other techniques involve severing the casing with a mechanical or hydraulic cutting apparatus. For example, a cutting apparatus is lowered from the surface towards a wellhead, often requiring the assistance of divers or a remotely operated vehicle to affix the apparatus to the wellhead. Once the connection is established, the cutting apparatus is activated to cut the casing. Upon completion of the cutting, the apparatus is disconnected from the wellhead, and raised to the surface. Then, another device or apparatus is subsequently lowered to the wellhead, such that it can affix to the wellhead. Then, the device and wellhead in combination can be raised to the surface. The need for multiple trips is time consuming and inefficient.

Accordingly, there exists a need for an improved cutting module that can perform rigless abandonment operations. There also exists a need for an improved cutting module that can perform a wellhead removal operation in a single trip.

SUMMARY OF INVENTION

In one aspect, embodiments disclosed herein relate to a rigless abandonment system that includes a surface vessel having an attached lifting device and a moonpool. The system further includes a cutting module configured to connect to a subsea wellhead, with the cutting module having a wellhead connector having an actuatable lock and release mechanism, a motor assembly, and a cutter. An umbilical line connects the cutting module to the surface vessel, wherein the lifting device is used to raise and lower the cutting module connected to the surface vessel through the moonpool.

In another aspect, embodiments disclosed herein relate to a method for performing rigless casing cutting and wellhead removal operations, the method includes positioning a surface vessel above a subsea wellhead, with the surface vessel having a moonpool and a lifting device. The method includes providing a cutting module having a wellhead connector having an actuatable lock and release mechanism, a motor assembly comprising a secured motor, and a cutter operatively connected to an output shaft of the motor assembly. The method further includes deploying the cutting module through the moonpool, wherein the cutting module is connected to the surface vessel by an umbilical line, guiding the cutting module into an operative position so that the cutter is located within a casing, actuating the lock and release mechanism to secure the cutting module to the subsea wellhead, expanding the cutter into engagement with the casing, and operating the motor to rotate the output shaft and cutter to cut the casing.

DETAILED DESCRIPTION

Referring to theFIG. 1, schematic representation of a rigless abandonment system according to embodiments of the present disclosure, is shown. In this embodiment, a rigless abandonment system may include a surface vessel2positioned over a subsea wellhead4located on the sea floor5. The use of the term subsea wellhead is not meant to be limiting, and for simplicity, may be referred to as a “wellhead” in describing embodiments disclosed herein. In addition, while shown only as a wellhead4, the wellhead4may be associated or connected with other common wellhead equipment, such as risers or a blow out preventer (BOP) (not shown).

The surface vessel2may be equipped with thrusters or a propeller system7to maintain the vessel2in an appropriate position and orientation to perform vessel operations. In one embodiment, the surface vessel2may be a drilling supply vessel (“DSV”). A DSV may provide multipurpose versatility and operational flexibility. For example, DSV's may provide floating, drilling, production, storage, and/or offloading capabilities. In some embodiments, DSV's may be used for pulling and/or carrying heavy loads. However, the type of vessel used in embodiments disclosed herein is not limited to a DSV.

Continuing withFIG. 1, the vessel2may be configured with at least one lifting device6that may be used for transferring loads to, from, and/or about the vessel2. In one embodiment, the lifting device6may be a crane. In another embodiment, the lifting device6may be a mounted derrick. The vessel2may also be configured with a moonpool8. The moonpool8may provide access to the sea, without the need to extend loads over an edge or side of the vessel2. In other words, the lifting device6may be used for raising and lowering loads through the moonpool8. In one embodiment, the lifting device6may raise and lower loads weighing up to 200,000 lbs. However, in other embodiments, the loads may exceed 200,000 lbs.

The moonpool8may be disposed within the surface vessel2in any number of locations (e.g., stern, aft, port, starboard, etc.), and is generally sufficient in width to allow deployment of large loads. In some embodiments, the lifting device6may be used to deploy a tool10through the moonpool8. In further embodiments, the tool may be a cutting module10used for cutting casing. While the location of the moonpool8may be at any position on the vessel2, the greatest amount of support for the lifting device6as it lowers a load through the moonpool may occur from a generally centralized position X. As depicted, the location of the central position X may be analogous to the midpoint (i.e., half-distance) of a vessel length L. In addition, greater support for the lifting device6may occur with the moonpool8also centralized with respect to a width (not shown) of the surface vessel2.

Referring toFIG. 2, a cross-section of a cutting module secured to a wellhead according to embodiments of the present disclosure, is shown. In this embodiment, the cutting module10is illustrated after it has engaged the wellhead4. Though the size of the cutting module10may vary depending upon the operation involved, the cutting module may have a general length in the range of 30 to 60 feet. In a specific embodiment, the cutting module may have a length in the range of 40 to 45 feet. The cutting module10may be configured to securely connect to the wellhead4via a wellhead connector12. In one embodiment, the wellhead connector12may include an actuatable lock and release mechanism14. In certain embodiments, the lock and release mechanism14may be hydraulically actuatable. The cutting module10may also include other features, such as a motor assembly13and a cutter16. Controlled deployment of the cutting module10through the moonpool (not shown) may be accomplished by any means known in the art. For example, the controlled deployment of cutting module10may include the use of an umbilical line18operatively connected to the lifting device (not shown). The cutting module and features contained therein may be made from materials known in the art that are commonly used for subsea operations.

The umbilical line18may serve other purposes besides providing the connection between the cutting module10and the vessel (not shown). For example, the umbilical line18may be used as an isolated conduit, such that it provides a protective barrier surrounding other components internal to the umbilical line18. The umbilical line18may be made of any suitable materials known in the art. For example, the umbilical line18may be made of materials that form a rigid, sturdy line, or alternatively, the umbilical line18may be made from materials that provide flexibility. In one embodiment, umbilical line18may be flexible enough to withstand multiple unwindings from a winding device (not shown) as a load is lowered via the lifting device (not shown). The winding device (not shown) may include devices known to those of an ordinary skill in the art, such as a drawworks winch or an auxillary winch.

As shown inFIG. 2, the umbilical line18may also include a plurality of other lines such as a combination of the electrical line19, the hydraulic line20, and the water line21. In the scope of embodiments disclosed herein, the umbilical line18, and any lines contained therein, may be sufficient in length to extend at least the entire distance from the surface vessel to the cutting module10, after the cutting module is secured to the wellhead4. Power and/or hydraulics required for operation of the cutting module10(including power required by a motor assembly13) may be delivered to the wellhead4by the connections extending from the surface vessel to the wellhead4provided via the umbilical line18.

Also referring toFIG. 3, a cross-section of a lifting device attached to a surface vessel according to embodiments of the present disclosure, is shown.FIGS. 2 and 3together show that the surface vessel2may have at least one hydraulic pump22, which may be used to supply pressurized fluids through the hydraulic line20. The hydraulic line20may have a first end20athat connects to the hydraulic pump22located on the surface vessel2, and may have a second end20bthat connects to the cutting module10. The pressurized fluids supplied by the pump22may be used for hydraulically actuating the wellhead connector12or components thereof, such as motor assembly13. In other embodiments, the hydraulic pump22may be used for other functions, such as transferring fluids between containers (not shown) located on the surface vessel2or transferring fluids between the surface vessel2and other vessels (not shown).

FIGS. 2 and 3also show that the surface vessel2may have at least one water pump23disposed thereon. In one embodiment, the water pump23may be a seawater pump. Similar to the hydraulic pump22, the water line21may have one end23aconnected to the water pump23located on the surface vessel2, and a second end23bconnected to the cutting module10. The water pump23may be used to run, for example, the motor assembly13.

Referring toFIG. 4, a cross-section of a cutting module secured to a wellhead in conjunction with a guidance mechanism according to embodiments of the present disclosure, is shown. In this embodiment, the motor assembly13may include a motor24, and an output shaft26connected to the motor24. In other embodiments, the motor assembly13may also include a tubular28, wherein the tubular28may be configured to operatively connect the output shaft26to the cutter16. In some embodiments, the motor24may be a hydraulic driven motor or a mud motor. Such a hydraulic motor may operate within a range of 0 to 300 gpm. In other embodiments, the motor24may be an electrical motor, where the electrical line19may be used for supplying electrical power thereto. In certain embodiments, the motor may exert up to 15,000 lbs torque.

The motor24may be mounted to the cutting module10according to any method known in the art. In one embodiment, the motor24is mounted to the cutting module10by a mounting device (not shown). Accordingly, connections to the cutting module10, illustrated in the drawings, may be made by flexible connections, such that members extending from the surface to the wellhead do not react to torque forces generated during the cutting operation.

FIG. 4also shows the cutter16. While depicted as having a single blade36, the cutter16may also have multiple blades attached thereto. Those of ordinary skill in the art will appreciate that the blades36may be formed from any material that is known in the art for casing cutting and subsea service, such as stainless steel or tungsten carbide. In one embodiment, the cutter16may be mechanically actuated to engage and cut the casing. In another embodiment, the cutter16may be hydraulically actuated. In certain operations, the cutter16may be used to cut casing of various diameters, D. In one embodiment, the cutter16may be used to cut casing having a diameter in a range of 8 to 36 inches. In another embodiment, the cutter16may be used to cut a casing having a diameter of about 9 and ⅝ inches.

The cutter16may include radially expandable cutting elements that are driven radially outwardly into engagement with the casing by hydraulic pressure applied via fluid flow through the central bore9of the tubular28. Pressurized hydraulic fluid (e.g., service water, seawater, etc.) may be applied to the cutter16via bore9. In some embodiments, the fluid from the bore9may also be used to cool the cutting blades36of the cutting device and to flush debris away from the blades36. Embodiments disclosed herein are not limited to the cutter as described, and those skilled in the art will appreciate that other cutting devices, including various geometries and orientations, may be used.

FIG. 4also illustrates a method of guiding the cutting module10to the wellhead4. Guiding the cutting module10may be useful when seas are turbulent or when a cutting operation needs to be performed expeditiously. As illustrated, the system may include a set of guide piles31embedded into the sea floor5and located proximate the wellhead4. There may further be a set of corresponding guide connectors32disposed on the guide piles31. In one embodiment, a set of corresponding connector lines33may be removably attached to the guide piles31and extend upwardly to a set of second connectors (34ofFIG. 1) disposed on the surface vessel (2ofFIG. 1). The connector lines33may also attach to the cutting module10. For example, the connector lines33may traverse a set of eyelets40disposed on the cutting module10. The eyelets40and connector lines33may operate together to keep the cutting module10properly oriented as it is deployed toward the wellhead4, or oppositely, as the cutting module10is raised to the surface.

Referring toFIG. 5, a downward view of the cutting module according to embodiments of the present disclosure, is shown. In this embodiment, there may be a plurality of longitudinally extending water flow areas50disposed on the cutting module10. In certain aspects, the flow areas50may facilitate the deployment of the cutting module10. The flow areas50may be generally circular and extend through the cutting module10so that the flow areas reduce resistance from the surrounding seawater as the module is raised or lowered from the surface vessel6(FIG. 1).

Referring toFIG. 6, a cross-section of a cutting module secured to a wellhead in conjunction with a remotely operated vehicle (“ROV”) according to embodiments of the present disclosure, is shown. In this embodiment, the ROV41may be equipped with a camera42and may be operable at any depth. Additionally, a diver (not shown) may assist in securing the cutting module10to the wellhead connector12. In some embodiments, the ROV41may have a connector device43for connecting to a ROV interface44disposed on the cutting module10. In other embodiments, the ROV41may be used for additional operations, such as determining whether the casing has been completely cut.

Embodiments disclosed herein also pertain to a method for performing rigless casing cutting and wellhead removal operations. The method may include various steps, such as positioning a surface vessel proximate a subsea wellhead. In one embodiment, the surface vessel may be a drilling supply vessel (“DSV”). A DSV may provide multipurpose versatility and operational flexibility. In some embodiments, DSV's may be used for pulling and/or carrying heavy loads. However, the type of vessel used in embodiments of the method disclosed herein is not limited to a DSV. In other embodiments, the surface vessel may include a moonpool and a lifting device.

The method may also include providing a cutting module for removing a wellhead, where the cutting module may include a wellhead connector and an actuatable lock and release mechanism. The cutting module may also include other features, such as a motor assembly and a cutter.

In one embodiment, the method may include deploying the cutting module through the moonpool, where the cutting module is connected to the surface vessel by an umbilical line. Controlled deployment of the cutting module through the moonpool toward the wellhead may be accomplished by any means known in the art. In addition to providing the connection between the cutting module and the vessel, the umbilical line may serve other purposes. For example, the umbilical line may be used as an isolated conduit, so as to provide a protective bather surrounding components internal to the umbilical line.

The method may further include guiding the cutting module into an operative position, such that the cutter may be located within a casing located below the wellhead. For example, the method may include using a set of guide piles and a set of corresponding guide connectors disposed on the guide piles to guide the cutting module into an operative position on the subsea wellhead. The guide piles may be embedded into the sea floor and located proximate the wellhead. There may also be a set of corresponding connector lines removably attached to the guide piles, and extending upwardly to a set of second connectors disposed on the surface vessel. The connector lines may also attach to the cutting module, such that the connector lines may traverse through a set of eyelets disposed on the cutting module. The eyelets and connector lines may operate together to keep the cutting module properly oriented as it is deployed toward the wellhead, or alternatively, as the cutting module is raised to the surface.

After the cutter is properly positioned within the casing, the method may include activating the lock and release mechanism, thereby securing the cutting module to the subsea wellhead via the wellhead connector. The cutter may include radially expandable cutting elements that are driven radially outwardly into engagement with the casing by a supply of hydraulic pressure. Pressurized hydraulic fluid (e.g., service water, seawater, etc.) may be applied to the cutter via a bore within the cutting module.

In some embodiments, a pump may be used for supplying pressurized fluid to the cutter for enabling cutting of the casing. Further, while the cutter may use hydraulic actuation, the cutter may also use mechanical actuation to engage and cut the casing. For example, once the cutter is expanded into engagement with the casing, a motor on the cutting module may be activated to rotate the output shaft and cutter, thereby cutting the casing. In certain aspects, the fluid from the bore may also be used to cool the cutting blades of the cutter and to flush debris away from the blades. While the cutting may be done with the cutter consisting of a single blade, the cutter may also have multiple blades attached thereto.

Once the casing has been cut, the method may further include ceasing the operation of the motor; actuating the lock and release mechanism to unlock the cutting module from the subsea wellhead; disconnecting the cutting module from the wellhead connector hub; and lifting the cutting module to the surface vessel by pulling up the umbilical line.

Alternatively, once the casing has been cut, the method may include ceasing the operation of the motor; removing the cutting module and subsea wellhead from a wellbore while they are secured to one another; and lifting the cutting module and subsea wellhead to the surface vessel by pulling up the umbilical line.

Methods disclosed herein may further include performing at least one of the providing, deploying, guiding, or expanding steps with a remotely operated vehicle (“ROV”). The ROV may be equipped with a camera and/or may be operable at any depth. In one embodiment, a diver (not shown) may be used with the ROV in securing the cutting module to the wellhead connector. In certain embodiments, the ROV may have a connector device for connecting to an ROV interface disposed on the cutting module. In still other embodiments, the ROV may be used for performing additional steps, such as determining whether the casing has been completely cut.

Advantageously, removing the cutting module and subsea wellhead while they are secured to one another may provide the advantage of removing both in a single trip. Further, the present disclosure may advantageously provide embodiments including a surface vessel that may be positioned to provide improved support and stability for a rigless abandonment system. A surface vessel having a centralized moonpool may also allow for greater loads to be deployed to a wellhead.

Other benefits and advantages of embodiments disclosed herein includes a wellhead removal technique that may be used during abandonment of a subsea oil or gas well, which does not require the use of explosive charges. Thus, the rigless abandonment system may provide improved environmental benefits.

While the present disclosure has been described with respect to a limited number of embodiments, those skilled in the art, having benefit of the present disclosure will appreciate that other embodiments may be devised which do not depart from the scope of the disclosure described herein. Accordingly, the scope of the disclosure should be limited only by the claims appended hereto.