Patent Grant
10753182
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The present invention relates to a subsea connection systems that allow fluid to flow between a flowline and a subsea structure. More particularly, the present invention relates to stabs that can be joined to ports of a flow channel of a subsea structure. More particularly, the present invention relates to the connection of high-volume flowlines to a flow channel of a subsea structure, such as a relief well injection spool.
In producing oil and gas from offshore wells, a wellhead is employed at the sea floor to regulate and direct the flow of hydrocarbons from the reservoir, through tubular risers, and to the surface where fluids are collected in a receiving facility located on a platform or other vessel. Normally, the flow of hydrocarbons is controlled via a series of valves installed on the wellhead, the risers, and the receiving facility at the surface. Other subsea equipment, such as manifolds and pipelines, also assist in directing the produced fluids.
Flowlines are used to interconnect pieces of subsea oil-field equipment for fluid communication. These flowlines generally take the form of somewhat flexible armoured hoses or pipes, provided with subsea matable connectors at either end. Typically, they are installed by being lowered into place from a pipe-laying vessel, with the final positioning and make-up of the end connectors carried out by divers or by remotely-operated vehicles (ROVs). Short ROV-installable hoses and pipes are used to interconnect adjacent pieces of subsea equipment. Examples of subsea equipment that may be interconnected using flowlines include subsea Christmas trees, manifolds, capping stacks, blowout preventers, or other subsea structures that require hydraulic connections. This equipment is located on the seabed.
When there are several different pieces of equipment to be interconnected, installation of the necessary pipes and flowlines can be time-consuming. An end of each flowline is generally lowered vertically to the seabed from a pipe-laying vessel. The flowline is then laid out horizontally between the points to be interconnected. The flowline ends must then be retrieved from the seabed by an ROV. The end connectors are aligned with the subsea equipment for make-up of the required fluid-tight connections.
A known type of flowline has a first part mounted to a piece of subsea equipment, such as a wellhead, and a mating second part fitted to the end of a flowline. In use, the second part is lowered toward the seabed and is stabbed from above into the first part. A pivot arrangement then guides the second part and attached flowline so as to hinge over into a generally horizontal position, in which the flowline may be laid away along the seabed, and in which the connector's first and second mating parts are axially aligned for make-up of a fluid-tight connection.
In order to connect various flowlines to items of equipment on the ocean floor, special connectors known as “flying leads” are often employed. The flying leads connect the ends of lines to subsea equipment, such as connecting to a control pod on a manifold or subsea tree at one end and to an umbilical termination assembly at the other end. In shallow waters, flying leads are connected the subsea equipment by divers. In deeper waters, one or more remotely-operated vehicles (ROVs) are utilized.
One of the problems with the existing systems is that, while they are effective for small bores of less than two inches, they are extremely difficult to install with respect to large bore applications (greater than two inches). In these large bore applications, the large pressures involved tend to create greater separation pressures. As such, they would generally be ineffective in supporting the connection under the effect of great pressures. As such, a need has developed so as to provide a subsea flowline connection assembly which can be used for large bore applications and which can withstand the great pressures involved in such applications.
Recently, there have been a great emphasis in the efforts to address the problems associated with well blowouts. Under the circumstances of a well blowout, the hydrocarbons from the well flow uncontrollably out of the wellhead. As such, it is been mandated that relief wells be prepared so as to address the potential of the blowout. The relief well extends from another wellhead at the seabed in a direction toward the hydrocarbon-producing wellbore. So as to stop the blowout, a high pressure fluid is directed through the relief well to the wellbore. The pressure of the fluid entering the wellbore should be sufficient to overcome the pressures in the reservoir formation and the pressure of the fluid flowing outwardly of the wellhead. As such, the present Applicant has developed a relief well injection spool so as to provide a connection with the wellhead of the relief well and the bore of the relief well.
This relief well injection spool, as described in U.S. application Ser. No. 15/335,805, is affixed to the relief well wellhead and includes a bore therein, along with flow channels that open to the bore from opposite sides of the relief well injection spool. These flow channels allow high-pressure fluid to be introduced into the bore of the relief well injection spool and, thereby, into the relief well.
In those applications where very high pressure fluids in the reservoir must be addressed, it is necessary to introduce high-volume and high-pressure fluids into the relief well injection spool. As such, it is necessary to install a four inch inner diameter flowline to the relief well injection spool. A hot stab connected with such a very large flowline is extremely heavy. As such, it would be too heavy to manipulate with an ROV. A very complex procedure would be required so as to properly install a very heavy hot stab to the port of the flow channel of the relief well injection spool. As such, a need has developed so as to facilitate the ability to install the large diameter flowline to the flow channel of the relief well injection spool. It is important to be able to remove the weight of such a hot stab from the ROV so as to allow for proper installation.
In the past, various patents have issued with respect to such hot stab assemblies. For example, U.S. Pat. No. 7,806,187 to the present Applicant, describes a connector assembly for connecting a hot stab to a hydraulic hose. The hot stab has a fluid conduit connector thereon. A hydraulic hose having a connector assembly at an end thereof is suitable for joining to the fluid conduit connector of the hot stab. A sleeve is affixed to the hot stab and to the hydraulic hose so as to extend over and surround the fluid conduit connector and the connector assembly. A jam nut is affixed to the tubular portion of the fluid conduit connector. The sleeve is threadedly connected to the threaded exterior surface of the jam nut. A crimped fitting is secured to an end of the hydraulic hose. A hose swivel extends around the crimped fitting and is affixed around the fluid conduit connector of the hot stab.
U.S. Pat. No. 8,388,363, issued on Mar. 5, 2013 to Karlsan et al., describes a connector assembly for connecting and/or disconnecting a conduit to or from a subsea pipeline. This a connector assembly includes a female cone element, a complementary male cone element, and a bolt tightening means. The tightening means includes a first stab member adapted to be received in a first receptacle in the female cone element. The first receptacle has an opening facing in an opposite direction of the cone of the female cone element for receiving the first stab member. A tightening bolt is provided in the first stab member within an inner end of the bolt by being adapted to engage the male cone element and with an outer end being accessible for the connecting and/or disconnecting operations.
U.S. Pat. No. 8,985,219, issued on Mar. 24, 2015 to K. D. Cruden, shows a system and method for connection and installation of underwater lines. This technique is intended to facilitate the formation of subsea connections. A free end of a stab connection system is moved into proximity with a fixed portion of the stab connection system at a subsea location. The free portion is initially engaged with the fixed portion via a docking probe. Subsequently, a local actuator is used to draw the free portion into an operating engagement with the fixed portion in which line couplers of the fixed portion are engaged with corresponding line couplers of the free portion.
U.S. Pat. No. 9,243,462, issued on Jan. 26, 2016 to Gutierrez et al., provides a high flow hot stab connection. The body of the connector has a first portion and a connection profile portion. A first port is formed through an outer surface of the first portion. A plurality of openings are formed through an outer surface of the connection profile portion. A plurality of fluid passageways extend through the body and are coupled between the first port and the plurality of openings. The subsea fluid connector can have a first fluid flow path extending through the plurality of fluid passageways between the first port through the outer surface of the first portion and the plurality of openings through the outer surface of the connection profile portion. A second fluid flow path extends through a fluid passage between a second port to the outer surface of the first portion and a third port through the outer surface of the connection profile portion.
U.S. Patent Application Publication No. 2013/0146301, published on Jun. 13, 2013 to the present Applicant, describes a subsea flowline connection assembly for use with a subsea structure. A junction plate is affixed to the subsea structure so as to support a flowline connector thereon. A receptacle is affixed to or adjacent to the junction plate. A fly-in connector assembly has a connector thereon. The connector of the fly-in connector assembly is engaged with the flowline connector of the junction plate. The fly-in connector assembly has a flow passageway in communication with the connector of the fly-in connector assembly. The receptacle has at least one slot form therein. The fly-in connector assembly has an insert member slidably received by the slot. The fly-in connector assembly has an actuator coupled to the connector thereof so as to allow an ROV to rotate an end effector so as to move the connector of the fly-in connector assembly toward the flowline connector.
It is an object of the present invention to provide a subsea flowline connection system and method which allows large diameter flowlines to be connected to a subsea structure.
It is another object of the present invention to provide a subsea flowline connection system which does not require an ROV to support the weight of the stab connection system.
It is another object of the present invention to provide a subsea flowline connection system and method which allows a large diameter flowline to be quickly and easily connected to the subsea structure.
It is still another object of the present invention to provide a subsea flowline connection system and method which allows high pressure and high volume fluids to be delivered to a relief well through a relief well injection spool.
It is still another object of the present invention to provide a subsea flowline connection system and method which assures a positive and fixed connection between the stab and the flow channel of the subsea structure.
It is still another object of the present invention to provide a subsea flowline connection system and method which allows the hot stab to be easily removed from the subsea structure.
It is still a further object of the present invention to provide a subsea flowline connection system which allows the connection system to be easily removed from the subsea structure and then transported for use elsewhere.
It is still further object of the present invention to provide a subsea flowline connection system and method that can be quickly deployed in emergency conditions.
These and other objects and advantages of the present invention will become apparent from a reading of the attached specification and appended claims.
The present invention is a subsea connection system that comprises a subsea structure having a flow channel therein, a stab having a flowline connected thereto, and a frame affixed to the stab. The flow channel has a port adjacent one end thereof. The subsea structure has a tool hanger positioned on an outer surface thereof adjacent to the port. The stab is adapted to engage the port of the subsea structure so as to allow a fluid to flow from the flowline into the flow channel of the subsea structure. The frame has a hook portion that is engageable with the tool hanger of the subsea structure so as to support the stab in alignment with the port of the flow channel. The frame is pivotable about the tool hanger so as to move the stab toward the port.
In the subsea connection system of the present invention, an actuator is positioned on the frame and is cooperative with the stab. The actuator is adapted to move the stab between a retracted position and an extended position. The extended position connects the stab to the port. In particular, the actuator can be a hydraulic actuator. This hydraulic actuator has a pair of ports opening outwardly thereof. One of the pair of ports of the hydraulic actuator is adapted to allow a remotely-operated vehicle to move the stab from the retracted position to the extended position. The other of the pair of ports of the hydraulic actuator is adapted to allow the remotely-operated vehicle to move the stab from the extended position to the retracted position.
A lock member is affixed to the frame. The lock member is engageable with the subsea structure so as to fix a position of the frame with respect to the port of the subsea structure. This lock member has a receptacle on either the subsea structure or the frame and a pin on the other of the subsea structure and the frame. The pin is rotatable so as to engage the receptacle. As such, the frame is locked to the subsea structure.
The flowline that is connected to the stab of the present invention has a diameter of greater than two inches. In the preferred embodiment the present invention, the flowline will have a four inch inner diameter. Also, in the preferred embodiment the present invention, the subsea structure is a relief well injection spool. A line can be affixed to the frame and extend upwardly therefrom. The line is payable so as to cause the frame to pivot about the tool hanger and the subsea structure.
The present invention is also a method of connecting a stab to a port of a flow channel of a subsea structure. This method includes the steps of: (1) lowering the frame and the stab toward the subsea structure; (2) pivoting the frame with respect to the subsea structure such that the stab is in proximity to the port of the subsea structure; and (3) actuating the stab within the frame so that the stab moves from a retracted position to an extended position. The extended position engages the port of the subsea structure so as to establish a fluid connection between the flowline and the flow channel.
The method of the present invention also includes moving the lowered frame and the stab to a position such that the hook portion is received by the tool hanger. The hook portion is rotated with respect to the tool hanger. The frame is locked to the subsea structure after the step of pivoting. In particular, a locking pin of the locking pin of the frame is engaged with a receptacle on the subsea structure.
In the method of the present invention, the step of actuating includes connecting a remotely-operated vehicle to a hydraulic actuator and flowing hydraulic fluid from the remotely-operated vehicle to the hydraulic actuator so as to move the stab from the retracted position to the extended position. The hydraulic actuator is affixed to the frame and is cooperative with the stab.
In the method of the present invention, the frame is connected to a line. The step of lowering includes paying out the line from a surface location until the frame and the stab are in proximity to the subsea structure. The line is further payed out from the surface location until the line becomes slack. This completes the step of pivoting. The flowline is connected to the stab so as to establish a fluid connection between the flowline and the stab. The flowline will have an inner diameter greater than two inches. Fluid can flow through the flowline and through the stab into the channel of the subsea structure. After completion of the operations, the stab is retracted within the frame so as to separate the stab from the port of the subsea structure, the frame is unlocked from the subsea structure, and then the frame and the stab are raised toward a surface location.
This foregoing Section is intended to describe, with particularity, the preferred embodiments of the present invention. It is understood that modifications to these preferred embodiments can be made within the scope of the present claims. As such, this Section should not to be construed, in any way, as limiting of the broad scope of the present invention. The present invention should only be limited by the following claims and their legal equivalents.
Referring to
The system 10 of the present invention is adaptable to a wide variety of subsea structures. In
As described herein, the flowline 18 will be a high-volume high-pressure flowline. In particular, so as to allow the relief well injection spool to carry out the necessary delivery of fluids so as to kill the well, the flowline 18 will have an inner diameter of greater than two inches. Preferably, the flowline 18 will have a four inch inner diameter. As such, the stab 14 will be a four inch stab. This stab will have a very large weight. As such, the frame 16 and the stab 14 would be too heavy to be carried and manipulated by a a remotely-operated vehicle. In
In
At this stage, the subsea structure 12 can be used for its intended purpose. To the extent that the subsea structure 12 is a relief well injection spool, the flowline 18 can deliver the high pressure high-volume fluids through the relief well injection spool, through the relief well, and into the main bore of the flowing well. When the flowing well has been capped, the stab 14 can be released, the frame 16 can be removed and the entire assembly can be returned to the surface by the downline 34 and the tool rigging 36.
It should be noted that in the installation of the system of the present invention, the connection between the hot stab and the subsea structure is accomplished through the use of gravity. Gravity will encourage they frame and the stab to rotate downwardly with respect to the tool hanger. The downline 34 and the tool rigging 36 will, at all times, support the weight of the assembly. The remotely-operated vehicle is only utilized for the purposes of fine manipulation and for actuation. The remotely-operated vehicle simply moves the supported weight of the assembly to its proper position at the tool hanger. The downline will continue to be played out until the downline becomes slack. Once the downline become slack, it is assured that the frame 16 has pivoted through its entire range of motion so as to be in alignment with the flow channel 20 of the subsea structure 12.
It should be noted that the flowlines having an inner diameter of two inches or less can be manipulated by a conventional remotely-operated vehicle. Additionally, the weight of such a hot stab on such small flowlines can be supported by the remotely-operated vehicle. As such, with conventional flowlines, it would not be necessary to use the frame assembly, the tool hanger, and actuators of the present invention. Since the present invention deals with flowlines having a diameter of greater than two inches and, in particular, an inner diameter of four inches, the present invention is able to establish a quick and easy deployment of such large flowlines in a secure and safe manner. As such, in the event of a well blowout, the relief well injection spool, along with the high volume, high-pressure flowline can be installed out with maximum efficiency.
The foregoing disclosure and description of the invention is illustrative and explanatory thereof. Various changes in the details of the illustrated construction can be made within the scope of the appended claims without departing from the true spirit of the invention. The present invention should only be limited by the following claims and their legal equivalents.
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| Number | Date | Country | |
|---|---|---|---|
| 20190055822 A1 | Feb 2019 | US |
