Patent Grant
10385630
This application is a U.S. National Phase application under 35 U.S.C. § 371 of International Application No. PCT/NO2016/050144, filed on Jun. 28, 2016 and which claims benefit to Norwegian Patent Application No. 20150914, filed on Jul. 13, 2015. The International Application was published in English on Jan. 19, 2017 as WO 2017/010889 A1 under PCT Article 21(2).
The present invention relates generally to the field of floating offshore platforms or vessels for the exploitation of undersea deposits of petroleum and natural gas. The present invention relates more specifically to risers tensioners and to a system for providing tension to risers which extend from a subsea wellhead or subsurface structure to a floating platform or vessel.
Offshore platforms for the exploitation of undersea petroleum and natural gas deposits typically support risers that extend to the platform from one or more wellheads or structures on the seabed. In deep water applications, floating platforms (such as spars, tension leg platforms, extended draft platforms, and semi-submersible platforms) are typically used. These platforms are subject to motion due to wind, waves, and currents. The risers employed with such platforms must therefore be tensioned to permit the platform to move relative to the risers. Riser tension must also be maintained so that the riser does not buckle under its own weight. The tensioning mechanism must accordingly exert a substantially continuous tension force to the riser within a well-defined range.
Hydro-pneumatic tensioner systems are one form of riser tensioning mechanism typically used to support risers known as “Top Tensioned Risers” on various platforms. A plurality of passive hydraulic cylinders with pneumatic accumulators are thereby connected between the platform and the riser to provide and maintain the necessary riser tension. Platform responses to the above mentioned environmental conditions, mainly heave and horizontal motions, create changes in platform position relative to the riser, causing the tensioning cylinders to stroke in and out. The spring effect resulting from the gas compression or expansion during a platform's vertical and horizontal movement relative to the seabed partially isolates the riser from the platform's motions.
Riser tensioners constituting such hydro-pneumatic tensioning systems comprise cylinders in which the cylinder rods are at least indirectly connected to the riser so that the pressure induced movements of the rod relative to its support results in the desired riser tensioning. Such hydro-pneumatic tensioner systems are presently produced in a variety of dimensions and sizes. Examples of typical state of the art riser tensioner systems are disclosed in WO 2004/013452, U.S. Pat. Nos. 4,886,397, 3,902,319, GB 2.109.036, WO 2012/016765 and WO 2014/090682.
Known riser tensioning systems include so-called “Direct Acting Tensioner” (DAT) systems and so-called “Wireline Riser Tensioner” (WLT) systems. An example of such systems is described in WO 2012/016765 (for example,
The location of the DAT systems within a moon pool area of a floating platform or vessel results in the risk of exposure to seawater which introduces challenges related to the corrosive environment and heavy accelerations of cylinder and rod. DAT systems may also show poor performance due to internal load deviations within the system. There may, for example, be flow resistance in the pipework/hoses between the tensioning cylinders and accumulator(s).
The alternative WLT system is large and may require a fairly complex arrangement if the system is to be applied to drilling vessels with a setback/fingerboard (for storing drill pipes, drill collars, etc.) that is situated lower than the drill floor. Such a low setback arrangement is demanding, and most users choose DAT systems in these situations. In addition to the complex arrangement in drilling vessels with low setback, the WLT systems suffer from high load variations due to friction over the plurality of sheaves. The repeated bending of the wire over a number of sheaves increases wire wear. A cut and slip configuration or complete replacement of the wire may therefore be required. The WLT systems are often heavy compared to other riser tensioning systems, typically around 500 MT depending on capacity.
An aspect of the present invention is to provide a riser tensioning system that at least mitigates the above disadvantages. An aspect of the present invention is more specifically to reduce the risk of seawater exposure while avoiding a complex arrangement when installing the system, thereby also making such a system suitable for use on a drilling vessel with a low setback.
A further aspect of the present invention is to provide a riser tensioning system having a low weight compared to the weight of a typical WLT system, for example, a weight comparable to the weight of a typical DAT system.
A further aspect of the present invention is to provide a riser tensioning system that does not require a wire rope cut and slip configuration.
In an embodiment, the present invention provides a riser tensioning system for providing a tensioning to a riser connected to a floating installation via a tension ring. The riser tensioning system includes at least one riser tensioner assembly. Each of the at least one riser tensioner assembly comprises a riser tensioning cylinder comprising a cylinder rod, at least one sheave, and a wireline comprising a first end and a second end. The first end is fixed to the tension ring, and the second end is fixed to the cylinder rod. The wireline is configured to extend between the tension ring and the cylinder piston via the at least one sheave.
The present invention is described in greater detail below on the basis of embodiments and of the drawings in which:
In an embodiment, the present invention provides a riser tensioning system for providing tensioning to a riser connected to a floating installation via a tension ring, the system comprising at least one riser tensioner assembly, each riser tensioner assembly comprising: a riser tensioning cylinder, the riser tensioning cylinder having a cylinder rod; at least one sheave; a wireline having a first end and a second end, the first end being fixed to the tension ring and the second end being fixed to the cylinder rod; whereby the wireline extends between the tension ring and the cylinder rod via the at least one sheave.
Providing a riser tensioning system with a wireline having its end fixed to the cylinder piston and extending to a tension ring via at least one sheave may eliminate the need to provide sheaves fixed to the riser tensioning cylinders, thus making these more flexible in their placement. Having the ends of the wireline fixed (i.e., fixedly connected) to the tension ring and the cylinder rod also allows for an approximately 1:1 transmission ratio between the cylinder rod and the tension ring, thereby avoiding frictional losses associated with systems having further sheaves for gearing.
The at least one sheave may be pivotable around an axis parallel to the riser during use.
The ratio between the diameter (d) of the wireline and the diameter (D) of at least one of the at least one sheave may be at least 30. This avoids the need to perform cut-and-slip or replacement of the wireline.
The riser tensioning system may comprise 4, 6, 8 or 10 riser tensioner assemblies. The cylinder rod may work in tension.
In an embodiment, the present invention provides a riser tensioning system for providing tensioning to a riser connected to a floating installation via a tension ring, the system comprising at least one riser tensioner assembly, each riser tensioner assembly comprising: a riser tensioning cylinder, the riser tensioning cylinder having a cylinder rod; at least one first sheave fixed to the cylinder rod; at least one second sheave; a wireline having a first end and a second end, the first end being fixed to the tension ring and the second end being fixed to the floating installation; whereby the wireline extends between the tension ring and the cylinder piston via the at least one first sheave and the at least one second sheave.
The at least one second sheave may be pivotable around an axis parallel to the riser during use.
The ratio between the diameter (d) of the wireline and the diameter (D) of at least one of the at least one first or second sheave may be at least 30.
The riser tensioning system may comprise 4, 6, 8 or 10 riser tensioner assemblies. The cylinder rod may work in tension.
In an embodiment, the present invention provides a floating installation comprising a riser tensioning system.
The floating installation may comprise a physical boundary that at least partly covers the riser tensioning cylinder of the at least one riser tensioner assembly, the physical boundary being configured to at least partly block any direct exposure of ambient water onto the riser tensioning cylinder during use.
The floating installation may further comprise a moon pool, wherein the riser tensioning cylinder of the at least one riser tensioner assembly is placed outside the moon pool.
The physical boundary may comprise the walls of the moon pool.
The riser tensioning cylinder of the at least one riser tensioner assembly may be placed below a drill floor and a deck of the floating installation.
The riser tensioning cylinder of the at least one riser tensioner assembly may be placed in a base structure of the floating installation, the base structure extending at least partly around the moon pool and below a waterline, wherein the riser tensioning cylinder is positioned in the base structure at least partly below the waterline.
A system according to the present invention is applicable for drillships, semi-submersibles, and buoys with both low setback arrangements and setback on drill floor.
The present invention is described further below under reference to the drawings. Numerous specific details are thereby introduced to provide a thorough understanding of embodiments of the system. One skilled in the relevant art, however, will recognize that these embodiments can be practiced without one or more of the specific details, or with other components, systems, etc. In other instances, well-known structures or operations are not shown, or are not described in detail, to avoid obscuring aspects of the disclosed embodiments.
In these systems, the tensioning cylinders 10 are located in a moon pool area 7 provided in the offshore installation, directly above the water line 8. The main components are the tensioning cylinders 10 which generate a pulling force on the riser 14. This pulling force is generated by a pneumatic pressure in a closed volume. The system is completely passive and needs very little attention during a drilling operation if well maintained. Each tensioning cylinder 10 normally has a positioning system to determine position, speed and direction of the rod movement. A cylinder rod side of the cylinder is connected to a high pressure accumulator (not shown) via a shut off valve, and a cylinder piston side of the cylinder is connected to a low pressure vessel (not shown) for nitrogen preservation. A hose and a gooseneck connects the tensioning cylinders 10 to shut off skids placed in moon pool area 7. DAT systems normally have a low weight compared to WLT-systems, which systems will be described below.
The WLT system is designed to keep close to constant tension in the marine riser 14 via a plurality of wirelines 11. It maintains the tension in each wireline 11, which is connected to a tension ring 13 on the marine riser 14. The wireline 11 from the tension ring 13 runs over pivot hinged idler sheaves 12 and then around the sheave assemblies 15a-d on each end of the tensioning cylinders 10. The wireline 11 may then run, for example, three turns around a snubber drum (not shown) with the end of wireline 11 being anchored to a clamp (not shown).
The WLT system is generally more protected from seawater exposure compared to the DAT system since the riser tensioning cylinders 10 are not located in the moon pool area.
The wireline 11a is connected at one end to a cylinder rod 60a of the tensioning cylinder 10a, runs over a sheave 12a and, at its other end, is connected to a tension ring 13 which supports a marine riser 14.
Similarly, the wireline 11b is connected at one end to a cylinder rod 60b of the tensioning cylinder 10b, runs over a sheave 12b and, at its other end, is connected to the tension ring 13 which supports the marine riser 14. The marine riser 14 extends downwards towards a sea floor along a riser axis 20 (see
Each of the sheaves 12a and 12b may be pivotable around a vertical axis. In use, the sheaves 12a and 12b may be fixed at a suitable point in the structure of the floating installation; the sheaves 12a and 12b can, for example, be fixed above or in the vicinity of a moon pool 7 (see
Each of the tensioning cylinders 10a-10h are connected to a respective wireline 11a-11h, each wireline 11a-11h extending between a cylinder rod (see, for example,
A physical boundary in the form of walls 7′ at least partly covers the tensioning cylinders 10a-10h and, optionally, the sheaves 12a-12h, so that the tensioning cylinders 10a-10h and the sheaves 12a-12h are not directly exposed to seawater, or at least partly protected from exposure to seawater.
In an embodiment, the walls 7′ can, for example, form part of the structure of the moon pool 7. The tensioning cylinders 10a-10h are advantageously placed outside the moon pool 7. In an embodiment, the tensioning cylinders 10a-10h can, for example, be placed outside a moon pool 7 and below a drill floor 5 and a deck 9 of the offshore installation 1.
The offshore installation 1 may also comprise a base structure 17, where the base structure 17 extends at least partly around the moon pool area 7 and below the waterline 8 when the offshore installation 1 is in operation. In an embodiment, the tensioning cylinders 10a-10h can, for example, be positioned in the base structure 17 at least partly below the waterline 8.
Considerable design flexibility is achieved by providing a riser tensioning system according to the present invention, allowing freedom to position the tensioning cylinders 10a-10h below a drill floor 5 and/or a deck 9 of an offshore installation 1, while maintaining various advantages of a direct-acting tensioning or a WLT system. Examples are low complexity, flexibility low friction, high reliability, and low maintenance requirements.
The possibility of locating the tensioning cylinders outside the moon pool area 7 and/or inside the base structure 17 facilitates very short piping for hydraulic fluid, thus reducing load variations due to hydraulic flow resistance. This can be achieved by placing any required accumulators and related hydraulic/pneumatic equipment close to the tensioning cylinders 10a-10h.
According to the present invention, the tensioning cylinders can also be placed in areas with strict space restrictions, for example, in a base structure 17 alongside vertical walls 7′, while any sheaves used can still be designed with a sufficient size to provide low wear on the wire rope. (This typically means a wire-to-sheave diameter ratio, D/d, of at least 30.) Arranging the tensioning cylinders 10a-10h in a position lower than the drill floor 5 and the deck 9 on a floating installation 1 is advantageous in terms of vessel stability and center of gravity, and to free up space for other equipment on the drill floor 5, deck 9, and in the moon pool area 7, where strict space restrictions typically exist.
It should be understood that any of the embodiments of the riser tensioning system 100 according to
The guide elements 70a and 70b may be in the form of guides or tracks along which the cylinder rods 60a and 60b are led. The guide elements 70a and 70b are advantageously fixed on the wall 7′, thereby allowing the cylinder rots 60a and 60b to extend parallel to the wall 7′.
A riser tensioning system according to any of the above embodiments will typically consist of 4, 6, 8 or 10 riser tensioners cylinders 10a-10h. The number of riser tensioner cylinders depends on the application and the load requirements.
The cylinder rods 60a, 60b of the riser tensioning cylinders 10a-10h in the riser tensioning system 100 or installation 1 according to the present invention as described above advantageously operate in tension when providing a force for tensioning the wirelines 11a-11h. This provides the advantage that long-stroke cylinders can be used, without the risk of bending or side forces, as opposed to cylinders operating in compression.
In the preceding description, various aspects of the apparatus according to the present invention have been described with reference to the illustrative embodiments. For purposes of explanation, specific numbers, systems and configurations are set forth in order to provide a thorough understanding of the apparatus and its workings. This description is not, however, intended to be construed in a limiting sense. Various modifications and variations of the illustrative embodiment, as well as other embodiments of the apparatus, which are apparent to persons skilled in the art to which the disclosed subject matter pertains, are deemed to lie within the scope of the present invention. Reference should also be had to the appended claims.
| Number | Date | Country | Kind |
|---|---|---|---|
| 20150914 | Jul 2015 | NO | national |
| Filing Document | Filing Date | Country | Kind |
|---|---|---|---|
| PCT/NO2016/050144 | 6/28/2016 | WO | 00 |
| Publishing Document | Publishing Date | Country | Kind |
|---|---|---|---|
| WO2017/010889 | 1/19/2017 | WO | A |
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| Number | Date | Country | |
|---|---|---|---|
| 20180202243 A1 | Jul 2018 | US |
