1. Field of the Invention
The present invention relates to a marine riser, of the type used in the transport of hydrocarbon fluids (gas, and/or oil, and/or water) from offshore wells.
2. Description of Prior Art
The marine riser typically includes a number of conduits for the transport of fluids and different conduits within the riser tower are used to carry the hot production fluids and the injection fluids which are usually colder. The Marine riser may form part of a so-called hybrid riser, having an upper portion (“jumpers”) made of flexible conduit and a lower portion made of rigid spools. U.S. Pat. No. 6,082,391 proposes a particular Hybrid Riser Tower (HRT™) consisting of an empty central core, supporting a bundle of riser pipes, some used for oil production some used for water and gas injection. This type of tower has been developed and deployed for example in the Girassol field off Angola. Insulating material in the form of syntactic foam blocks surrounds the core and the pipes and separates the hot and cold fluid conduits. Further background is to be published in a paper Hybrid Riser Tower: from Functional Specification to Cost per Unit Length by J-F Saint-Marcoux and M Rochereau, DOT XIII Rio de Janeiro, 18 Oct. 2001. Other forms of riser tower are described in applications WO 04/051051 and WO 04/051052.
It has been current practice to connect Riser Towers to a FSPO using flexibles in a catenary configuration. Alternatively an earlier version of the Hybrid Riser Tower was connected to a semi-submersible with flexibles in a catenary position (see Garden Banks 388, Offshore Engineer August 1994).
It is also known to attach a riser (in a “lazy wave” or “lazy s” configuration) to a vessel such as a Floating, Production Storage and Offloading vessel (FPSO) via a turret type connector attached to the top of the riser and which mates with a recess usually in the vessel's hull. The turret usually comprises a rotating table and a set of swivels. In a disconnectable turret the rotating table is released and the swivels remain on board. This then retains the vessel at a fixed place but allows it to rotate with the rotating table according to sea and weather conditions, while also allowing the fluid to pass through this connection into the vessel.
In difficult meteorological and sea conditions, particularly when in deepwater and ultradeep water in areas where typhoon or hurricanes can strike, it may be required to disconnect the floating production facilities. It is important that the load imposed on the turret when it is disconnected remains minimal. A substantially rigid riser tower such as a HRT is a suitable means of having a very small load and carrying a number of connections (lines and umbilicals) to the turret.
However, little work has been performed to attach a riser tower or HRT arrangement to a disconnectable turret or loading buoy.
In a first aspect of the invention there is provided an apparatus for the connection/disconnection of a marine riser to a floating vessel comprising at least one connecting line, attachable to said riser at its lower end and arranged to be moveable between a first helical configuration which allows connection between the riser and the floating vessel and a second helical configuration wherein said connecting line is disconnected and retracted from said floating vessel.
An advantage of the helical path is to maintain a nearly constant curvature consistent with the bending radius of the connecting line (such as a flexible or umbilical), and also to require only a short length of connecting line which is beneficial for vertical loads, and head loss.
Said connection may be via a turret attached to said connecting line, said turret being engagable with said vessel. Alternatively said connection may be via a loading buoy, remote to said vessel, said loading buoy being attached directly to the connecting line or via a turret attached to the connecting line and being engagable with said loading buoy. Said marine riser installation may be for the production of hydrocarbon products from the seabed to surface.
Said connecting line may consist of one or more flexible conduit or one or more umbilicals or a combination of flexible conduits and umbilicals.
A plurality of connecting lines may be provided in similar helical configurations, offset angularly about a common axis. Said similar helical configurations may in particular have the same radii and heights. In one embodiment six conduits are arranged around the axis. Applying the invention to a plurality of connecting lines arranged with similar but angularly offset helical paths helps minimize clashing while permitting a compact arrangement.
Said marine riser may be a substantially vertical riser tower, such as a hybrid riser tower. Substantially vertical in this case means vertical as known in the art, and in comparison with catenary risers and other such configurations. However, because such a riser tower may be very long, it may bend or lean some way off true vertical.
Said apparatus may be arranged so that connection to said floating vessel is made when said vessel is positioned substantially vertically above said marine riser and/or disconnectable turret.
The first helical configuration may be stretched relative to the second helical configuration, along substantially the same axis.
The axis of said first and second helical configurations may be substantially vertical.
The first helical configuration may comprise fewer than ten, five or even two complete turns around its axis. In one embodiment there in only one turn, half a turn is also feasible.
Said vessel may be an floating production, storage and offloading vessel (FPSO). Alternatively it could be any type of offshore production unit.
Said apparatus may further comprise a support frame to support said connecting line(s). Said support frame may be anchored to the seabed. Said connecting lines may comprise bend stiffeners or bend restrictors.
A connecting point of the connecting line may be moveable between sea level and 20-40 meters below sea level, the first helical configuration of a connected line may have a height between 80 m and 110 m, and the second helical configuration of a disconnected line may have a height of between 50 and 80 m.
In a practical embodiment the line may be moveable between sea level and 30 meters below sea level, the first helical configuration the of a connected line may have a height of 95 m, and the second helical configuration of a disconnected line may have a height of 65 m.
The radius of the apparatus in said first helical configuration may be in the range 2 m to 8 m while the radius in the second helical configuration is larger.
In a further aspect of the invention there is provided a method of installation of a connecting line from a marine riser to a buoy comprising the steps of:
The buoy may be a disconnectable turret for connection to a ship. It may be moored to the seabed by anchors and a line. Said mooring may hold it between sea level and 50 m below sea level.
The vessel may make less than one complete circle, a single complete circle, or a number of circles of the substantially circular path, depending on the number of turns in the helical configuration desired.
The connecting line may be lowered from the vessel from a reel or by a winch. It may be connected directly or via a line or rope to the vessel during the first three steps of the method.
Said method may be repeated for a number of connecting lines.
The connecting line may consist of one or more flexible conduit or one or more umbilicals or a combination of flexible conduits and umbilicals.
Embodiments of the invention will now be described, by way of example only, by reference to the accompanying drawings, in which:
Referring to
Vertical riser towers are provided at 112 and 114, for conveying production fluids to the surface, and for conveying lifting gas, injection water and treatment chemicals such as methanol from the surface to the seabed. The foot of each riser, 112, 114, is connected to a number of well heads/injection sites 100 to 108 by horizontal pipelines 116 etc.
Further pipelines 118, 120 may link to other well sites at a remote part of the seabed. At the sea surface 122, the top of each riser tower is supported by a buoy 124, 126. These towers are pre-fabricated at shore facilities, towed to their operating location and then installed to the seabed with anchors at the bottom and buoyancy at the top.
A floating production and storage vessel (FPSO) 128 is moored by means not shown, or otherwise held in place at the surface. FPSO 128 provides production facilities, storage and accommodation for the wells 100 to 108. FPSO 128 is connected to the risers by flexible flow lines 132 etc arranged in a catenary configuration, for the transfer of fluids between the FPSO and the seabed, via risers 112 and 114. Such flexible flow lines do not allow for straightforward disconnection in difficult meteorological conditions. Also in such arrangements the FPSO itself cannot be easily removed from its anchoring system.
Individual pipelines may be required not only for hydrocarbons produced from the seabed wells, but also for various auxiliary fluids, which assist in the production and/or maintenance of the seabed installation. For the sake of convenience, a number of pipelines carrying either the same or a number of different types of fluid are grouped in “bundles”, and the risers 112, and 114 in this embodiment comprise bundles of conduits for production fluids, lifting gas, injection water, and treatment chemicals, methanol.
Attached to the top of this buoy via a helical connecting line (not shown on this drawing), and also anchored to the seabed by suction anchors 205, is the disconnectable turret or loading buoy. This is shown here in its operational position 211 where it can be connected to a vessel, and in a retracted (disconnected) position 211′.
When the turret is connected it is at sea level and mated with the vessel. When the turret is disconnected, it takes, under the action of its mooring, an equilibrium position about 30 m below. The top of the HRT does not move vertically.
An advantage of this helical arrangement is that the curvature of the connecting lines is kept relatively constant between the two positions and thus remains consistent with the bending radius of the flexible pipelines or umbilicals which make up the connecting lines. For instance, assuming an average height of the helix to be 80 m (the turret being moveable from 65 m above the riser tower to 95 m above the riser tower), it can be shown that the average radius of the helix would be 8.4 m (that is the radius being 12 m and 4.73 m respectively). From this it can be shown that the average radius of curvature would be 21.13 m, and would stay in the range of 19.85 m to 22.35 m. This is well outside the minimum radius of curvature of the flexible. Obviously these figures are for illustration only.
A further advantage is that the length of these connections can be kept to a minimum as the turret (and the FPSO) can now be conveniently located in a geostationary position directly above the riser tower.
The embodiments mentioned above are for illustrative purposes only and other embodiments and variations can be envisaged with departing from the spirit and scope of the invention.
Number | Date | Country | Kind |
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0427920.4 | Dec 2004 | GB | national |
This application claims priority from U.S. Provisional Application No. 60/617,984 dated 11 Oct. 2004 and GB 0427920.4 dated 21 Dec. 2004, incorporated herein by reference.
Filing Document | Filing Date | Country | Kind | 371c Date |
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PCT/EP2005/012030 | 10/10/2005 | WO | 00 | 11/14/2007 |
Publishing Document | Publishing Date | Country | Kind |
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WO2006/040197 | 4/20/2006 | WO | A |
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3597779 | Morgan | Aug 1971 | A |
3913668 | Todd et al. | Oct 1975 | A |
5553976 | Korsgaard | Sep 1996 | A |
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1573131 | Aug 1980 | GB |
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WO 9636528 | Nov 1996 | WO |
WO 03031765 | Apr 2003 | WO |
Number | Date | Country | |
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20080214072 A1 | Sep 2008 | US |
Number | Date | Country | |
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60617984 | Oct 2004 | US |