The invention relates to a subsea coiled tubing injector and, more particularly, to a subsea injector with a pressure compensated drive system.
Coiled tubing has been used for decades in land-based hydrocarbon recovery operations to perform various well treatment, stimulation, injection, and recovery functions more efficiently than with threaded tubulars. In a conventional land-based operation, the coiled tubing injector may use a gear drive mechanism with conventional bearing assemblies to reliably and efficiently transmit power to the coiled tubing.
While conventional coiled tubing injectors may work satisfactorily for land-based or shallow-water operations, they would not work in deeper water because the drive mechanism for the injector is not sufficiently protected from the subsea environment. Specifically, the hydrostatic pressure at such depths is sufficient to penetrate past the seals used on lubricated components such as the gear case and bearing assemblies of land-based equipment. A proposed solution to this problem is disclosed in U.S. Pat. No. 4,899,823, whereby the tubing injector is protected subsea by an enclosure surrounding substantially the entire tubing injector. Seals are provided between the enclosure and the coiled tubing above and below the injector. An obvious disadvantage of this solution is the size of the housing and complexity of enclosing the entire injector with the housing.
An improved coiled tubing injector for subsea use is therefore desirable.
A pressure-compensated tubing injector is disclosed for injecting coiled tubing into a subsea wellhead or flowline. The injector comprises a traction device including a plurality of opposing grippers carried on respective opposing chain loops for gripping engagement with the coiled tubing and longitudinally movable with the coiled tubing. A plurality of outboard bearing assemblies guide movement of the opposing chain loops. The bearing assemblies may comprise first and second pairs of bearing assemblies, each pair for guiding movement of a respective one of the opposing chain loops. A drive unit powers the opposing chain loops to move the chain loops and the grippers carried thereon. The drive unit includes a sealed gear case. A pressure compensator in communication with the sealed gear case is responsive to subsea pressure, such that pressure within the sealed gear case is functionally related to subsea pressure.
The pressure compensator may be placed in communication with one or more of the outboard bearing assemblies, such that pressure within the one or more compensated outboard bearing assemblies is functionally related to subsea pressure.
The pressure compensator may comprise a compensator housing structurally separate from the gear case and bearing assemblies and having a sealed internal cavity in communication with the sealed gear case. A movable element within the compensator housing is responsive to subsea pressure for varying a volume of the internal cavity. A biasing member may be included for biasing the movable element, preferably to increase pressure.
Conduit may extend between the pressure compensator and the sealed gear case for placing the pressure compensator in fluid communication with the sealed gear case. Conduit may also extend between the pressure compensator and the one or more outboard bearing assemblies, for placing the pressure compensator in “direct” fluid communication with the bearing assemblies. Conduit may alternatively extend between the sealed gear case and the one or more outboard bearing assemblies, for placing the pressure compensator in “indirect” fluid communication with the bearing assemblies.
The bearing assemblies may each comprise a self-contained a pressure compensator. A movable element is within a bore of a bearing shaft, and the bore is in fluid communication with a bearing cavity containing a lubricant within the bearing assemblies. The movable element is exposed on an inner surface to the lubricant and on an outer surface to subsea pressure.
A plurality of rollers 20, as shown in
The bearing assemblies 52 and an injector gear case 54 as shown in
A commercially-available pressure compensator 60 is conceptually shown assembled with the injector 10 in
The external pressure compensator 60 may be plumbed to the gear case 54 via conduit 62 to place the pressure compensator 60 in communication with the gear case 54. The bearing assemblies 52 may then be placed either in “direct” communication with the pressure compensator 60 by plumbing directly between the pressure compensator 60 and bearing assemblies 52, or “indirect” communication by plumbing from the gear case 54 to the bearing assemblies 52. Alternatively, multiple external compensators (not shown) may be used to plumb to selected components. For example, one compensator 60 may be plumbed to the gear case 54, and directly or indirectly to the two upper bearing assemblies 52 closer to the gear case 54, and another compensator (not shown) may be positioned more closely and plumbed to the lower bearing assemblies 52 further from the gear case 54.
Instead of plumbing an external compensator to the bearing assemblies 52, the bearing assemblies 52 may include a self-contained pressure compensator 70 within a bore 72 of a shaft 74, as shown conceptually in
The cutaway view of
The coiled tubing injector of this invention is not limited to downhole recovery operations. For example, the tubing injector may also be used to perform pipeline maintenance operations. The pipeline version of the coiled tubing injector may be landed on the seabed and attached to an access valve in the pipeline using a lightweight connector. The pressure control system may consist of a gate valve a shear ram, and a set of strippers. Tools and/or fluid may then be conveyed in and out of the pipeline using the coiled tubing. Because the coiled tubing may be used to pull the tools back from where they were launched, there is no need for a pigging loop. The use of coiled tubing also allows various fluids to be pumped into the pipeline, which would be especially beneficial for removing sand or paraffin.
Although specific embodiments of the invention have been described herein in some detail, it is to be understood that this has been done solely for the purposes of describing the various aspects of the invention, and is not intended to limit the scope of the invention as defined in the claims which follow. Those skilled in the art will understand that the embodiment shown and described is exemplary, and various other substitutions, alterations, and modifications, including but not limited to those design alternatives specifically discussed herein, may be made in the practice of the invention without departing from the spirit and scope of the invention.
This application claims priority from U.S. Ser. No. 60/433,259 filed Dec. 13, 2002.
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