The present invention relates to a riser top connector and more specifically connectors for connecting an FPSO (Floating Production, Storage and Offloading) unit or similar units, to a riser tower assembly via a flexible jumper.
More precisely, the present invention relates to a riser top connector assembly, comprising a first connector part arranged on a flexible jumper prepared for connection with a second connector part arranged on top of a marine riser tower assembly projecting from the seabed, which first connector part is provided with suspension means adapted to engage with supporting means on the second connector part in order to be supported and be able to tilt in the marine riser tower assembly.
A riser top connector assembly of this nature is known from WO 2012/076520. Other example of prior art are U.S. 2012/0090152, U.S. 2010/314123, U.S. 2012/145407, NO 178901, WO 2014/114890 and GB 2504484.
(The riser top connector is adapted to connect a flexible jumper from an FPSO or similar unit to the top of a riser tower. The flexible jumper provides flexibility for mutual movement of the FPSO and riser tower. The jumper hangs in the sea in a catenary from the riser tower assembly to the FPSO.
To ensure stable fluid connection between the end hub of a flexible jumper and the end hub of a riser extending upwards from the seabed, it is known to arrange the riser end hub in a riser tower assembly below the surface. The mechanical connection between the two hubs must withstand large forces. The weight of jumper exerts a significant load onto the connection and as the jumper may be pulled in various directions with respect to the riser tower assembly the load will vary. Such pulls may for instance be the result of weather conditions or water currents.
The present invention provides a riser top connector assembly which ensures that mutual forces between the jumper end hub, at the end of the flexible jumper, and the riser end hub, at the end of the riser, do not appear crosswise to the centre axis of the two end hubs. That is, regardless of which direction in which the flexible jumper is pulled, for instance in a direction straight downwards or a direction closer to the horizontal, the forces between the two end hubs will substantially be directed parallel to the two coaxially arranged centre axes of the two mating end hubs.
A riser top connector assembly of the introductory defined kind is provided, which is distinguished in that said first connector part includes a housing that receives an extendable termination hub having a connector attached thereto, which jumper termination hub is alignable with a freely projecting riser hub on said second connector part when said first connector part is being tilted relative to said marine riser tower assembly,
said jumper termination hub is extendable towards said riser hub on said second connector part by means of an actuator,
said jumper termination hub is, when extended from said first connector part housing, prepared for connection with said riser hub by means of said connector, and
said second connector part includes a load carrying frame structure straddling over the respective hubs when connected in order to route the load path away from said hubs and connector when connected.
In this way most of bending moments are relived from the respective hubs and the connector, which should then be far more safe for both rupture and leakages.
The above described coupling motion, which moves the two end hubs from a non-connected state into a connected state, is a combined pivoting and translatory motion between the jumper termination hub structure and the riser tower assembly.
The connector can i.a. be either a clamp connector, a collet connector or a dog type connector.
In one embodiment the actuator will be able to extend the jumper termination hub from the first connector part housing, either by a stroke tool or a pulling tool.
Any suitable tool able to perform a substantially rectilinear displacement of the jumper termination hub is conceivable to use.
Preferably, the jumper termination hub is externally designed with centralizing means, which centralizing takes place and being performed during the extending motion of the jumper termination hub within and relative to the first connector part housing.
Conversely, the first connector part housing can be internally designed with centralizing means, which centralizing takes place and being performed during the extending motion of the jumper termination hub within and relative to the first connector part housing.
In one embodiment, the first connector part and the second connector part can have projecting orienting means, which projecting orienting means mate and engage during final relative motion between the respective connector parts.
In still another embodiment, the stroke tool can be detachably arranged on the first connector part housing and jumper termination hub.
Normally the connector can be operated by means of a torque tool carried by an ROV. Other types of connectors can be actuated by integrated hydraulics or a different kind of ROV tool. Also a diver can operate the connector.
In another embodiment of the invention, the first connector part housing is shortened and omit the orienting means and is internally designed with centralizing means, which centralizing takes place and being performed during the extending motion of the jumper termination hub within and relative to the first connector part housing.
Corresponding to the first aspect of the invention, the embodiment involving the guide rod and alignment funnel combination could also be another type of force-transmitting structure.
Having described the invention in general terms above, a more detailed example of an embodiment will be given in the following with reference to the drawings in which
It is preferable and beneficial that the flexible jumper 9 hangs in a catenary way between the FPSO and the riser tower assembly 7, and in such a way that the jumper connects to the riser end in an inclined position. If this was a more vertical position, the jumper would have been needed to be much longer, or a substantially higher load would have been experienced in the transition between the riser and the jumper. Similarly, if the jumper had extended more horizontally, after the connector, a corresponding load would have been experienced, but in opposite direction.
A riser top connector 11 connects a jumper termination structure 13 to the riser tower assembly 7. At an end section of the flexible jumper 9, it is connected to a bend stiffener 15, which restricts the bending of the flexible jumper 9 in the proximity of the jumper termination structure 13. The bend stiffener 15 connects to the jumper termination structure 13 along a jumper termination axis 6 along which the flow path of the jumper end section follows.
The previous jumper termination structure 13 is now termed a first connector part 21, which include a first connector part housing 22 that receives an extendable jumper termination hub 23 and a clamp connector 24 attached to the termination hub 23. A flange 25 is shown in the lower end the termination hub 23, to which the jumper (not shown) extending to the FPSO is to be secured.
An actuator, here shown as a stroke tool 26, is designed to act between the first connector part housing 22 and the jumper termination hub 23 in order to enable extension of the termination hub 23 out of the first connector part housing 22. Such stroke tool could be of any conceivable nature, preferably hydraulically operated.
A tool adapter 27 is arranged on the clamp connector 24. The tool adapter 27 is normally operated by a torque tool (not shown) carried by an ROV when in use and submerged. The tool adapter 27 is connected to a screw 28, which, when turned, is able to reduce the opening diameter of the clamp connector 24 in order to pull the respective hubs to engagement.
The first connector part housing 22 includes a pair of diametrically located and projecting journals 29 designed to pivotally suspend the first connector part 21 in a second connector part 40.
The first connector part housing 22 also includes a pair of upwards projecting guide pins 30 designed to mate with receptacles 41 in the second connector part 40. In a second embodiment, as illustrated in
The riser top connector assembly 20 includes the second connector part 40 that initially is separate from the first connector part 21. Together the first and second connector part 21, 40 constitute the riser top connector assembly 20.
The second connector part 40 includes supporting means in the form of cradles 42 able to receive the projecting journals 29 arranged on the first connector part housing 22.
The second connector part 40 further includes receiving means 43 enabling guiding of the first connector part 21 into correct positioning and engagement with the second connector part 40 as illustrated in
The second connector part 40 has a frame structure 45 which also have the material function to remove the bending moment between the hubs 23, 44 and have them transferred to the frame structure 45. The riser hub 44 is the termination end of the riser 5 that in this end portion extends like a gooseneck section 46. This end portion is axially retained to the frame structure 45 near the riser hub 44. The riser hub 44 is freely projecting from the frame structure 45.
Further,
Such rotation may be performed by either moving the installation vessel a little, or pulling in some jumper length into the installation vessel. In this way the termination hub will tilt and finally lock as described in more detail with reference to
As shown in
A locking arrangement is also clearly shown in
The
The concept shown in
For both solutions it is imperative that the riser hub 44 (upper) is retained to the frame structure 45 in axial direction, but is allowed to move in radially direction. The riser hub 44 is also allowed to twist a little relative to nominal axial direction. In this way the riser hub 44 will give in when the bending moment from the flexible jumper 9 is received, and the jumper end is moving until resistance is received from the termination hub 23 or the guide pins. A great part of the bending moment and the shear force is thus taken up by this contact instead of being transferred through the hubs and the connector to the riser. All this is provided that the gooseneck and the upper part of the riser have some certain flexibility. This is solved in that a certain length is present from the riser hub to where the riser is supported.
Number | Date | Country | Kind |
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20141224 | Oct 2014 | NO | national |
Filing Document | Filing Date | Country | Kind |
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PCT/NO2015/050184 | 10/7/2015 | WO | 00 |