The present invention relates to a buoyant offshore structure, such as an offshore platform or spar.
Typical offshore structures such as semi-submersible or tension-leg platforms, or a spar, comprise a hull part that extends into the water, and which has sufficient buoyancy to support a work area or platform above the water surface. The hull of a platform typically comprises a structure of a plurality of horizontal pontoon elements connected by nodes, which supports a plurality of column elements vertically upstanding from the nodes, which column elements in turn support the work platform or topside above the surface of the water. In general, the size and configuration of the pontoons and the size, number and shape of columns are governed by the size and weight of the work platform and associated payload to be supported. Such a platform is for example disclosed in International patent application publication No. WO 2010/042937.
During operation of an offshore platform it can be needed to store chemicals in substantial quantities, such as for use during a drilling operation, for a treatment of the subsea formation, or for enhanced oil recovery. Certain such chemicals can be corrosive. Over the service life of such platform of typically many years, different chemicals may need to be stored.
There is a need in the art for an improved storage for liquid on a buoyant offshore structure.
In accordance with the invention there is provided a buoyant offshore structure, comprising
By providing a storage tank that is vertically supported from the surface end of the hull element and can be lifted, such tank can be easily replaced should that be needed during the service life of the offshore structure, e.g. in case of corrosion.
In some embodiments, the buoyant offshore structure comprises a plurality of storage tanks for liquid. Each of these tanks can be arranged such that it is separately removable by lifting from the hull element's surface end. Providing more storage tanks enables storing of a greater volume and/or different types of liquids or chemicals.
In some embodiments the hull element comprises a sump tank and the at least one storage tank is at least partially arranged in the sump tank. In particular, a plurality, such as two or more storage tanks, can be at least partially arranged in the sump tank.
In some embodiments the hull element can be substantially column-shaped, such as substantially cylindrical.
In some embodiments the sump tank can be substantially column-shaped, such as substantially cylindrical.
In some embodiments the storage tank can be substantially column-shaped, such as substantially cylindrical.
In some embodiments the buoyant offshore structure comprises additional hull elements with an inner space, a surface end and an underwater end. The additional hull elements can also be substantially column shaped, such as substantially cylindrical.
In some embodiments, two or more of the hull elements can each comprise one or more storage tanks, such as two or more storage tanks.
In some embodiments, two or more of the hull elements can each comprise one or more sump tanks, wherein at least one of the sump tanks comprises a liquid storage tank.
In some embodiments, the at least one storage tank is laterally supported between the surface end and the underwater end. In embodiments wherein the storage tank is arranged in a sump tank, the storage tank can suitably be laterally supported at one or more locations in the sump tank, such as at different heights. In some embodiments a plurality of storage tanks is provided which are laterally supported between the surface end and the underwater end. In some embodiments the lateral support of one storage tank or a plurality of storage tanks can provided within a sump tank.
In some embodiments, the buoyant offshore structure comprises a corrosion-resistant metal at an inner surface. In particular, the corrosion resistant metal can be more corrosion resistant than carbon-steel. The corrosion resistant metal can be stainless steel or super duplex steel.
In some embodiments, the at least one storage tank suspended in the hull is accessible from the surface end of the hull element for at least one of: introducing liquid into the storage tank, removing liquid from the storage tank, placing, removing or servicing a pump in the storage tank. Such pump can be a submersible pump that can be installed and is accessible from the top of the storage tank (surface end of the hull element).
In some embodiments the top of the tank is accessible by a crane.
The invention shall now be further described by way of example and with reference to the drawings, wherein
Where like reference numerals are used in the Figures, they refer to the same or similar elements when they carry the same number.
Reference is made to
Reference is made to
Compartmentalization is preferred in order to prevent sinking of the structure in case of a leak due to e.g. an accident such as boat impact, corrosion, or another form of damage. Providing a sump tank, or a plurality of sump tanks, provides additional compartmentalization.
In some embodiments, the storage tank is laterally supported within the sump tank, at one or more locations between the surface end and the underwater end, such as at vertically separate locations. Preferably, lateral supports are releasably or removably arranged. Lateral supports can for example be provided by bolted connections, and they can be unbolted if the removal of the storage tank is needed. The lateral supports can be arranged such that they can be installed, in particular removably installed, from the surface end of the column. In some embodiments support can be provided by a person descending into the hull and unbolting the storage tank before it is lifted up by a crane.
The exemplary embodiment of
Reference is made to
In the embodiment shown in this example, the hull element comprises three sump tanks 17, each substantially as described with reference to
The storage tank or tanks in the embodiments referred to herein suitably comprise a corrosion-resistant metal at an inner surface, that is more corrosion resistant than carbon-steel, for example stainless steel or super duplex steel. In some embodiments the tank can have an inner cladding of such metal, or in some other embodiments it can be integrally formed of such metal.
In a storage tank a pump 24 can be arranged, such as an electrical submersible pump. This is only visible in
The columns, storage tanks, sump tanks in the embodiments as shown in the drawings are all substantially cylindrical. It shall be understood that they can have different shapes and lengths, e.g. different cross-sectional shapes such as polygonal, and/or changing cross-sectional shape or diameter along their vertical length. More than one upright hull element can be arranged per node.
Storage tanks are suitably arranged such that they can be inserted from the top 12 of the column. Suitably they are hung off from the top of the column Suitably they can also be retrieved by lifting from the surface end or top of the column, such as using a crane or other lifting device. This enables servicing and removing or replacing any of the storage bullet tanks throughout the life of the offshore structure. Suitably lateral supports are released or removed before lifting. In some embodiments, all storage tanks are removable by lifting from the surface end. In some embodiments, only part of the storage tanks are removable by lifting, for example only storage tanks that are arranged in a sump tank.
Reference is made to
Reference numeral 26 in each column indicates a conventional access shaft of the column.
Each of the columns is divided in compartments by suitable vertical walls 28, which can also be referred to as bulkheads, which are suitably water-tight. As can be seen, the columns 6c and 6d that do not have storage tanks are subdivided into vertical compartments by walls 28. The compartmentalization by vertical walls superimposes the compartmentalization by horizontal flats as discussed hereinabove, so that a plurality of smaller compartments is formed. Columns 6a and 6b that have storage tanks in accordance with the present invention have only 3 vertical walls 28, but nevertheless can achieve sufficient compartmentalization by virtue of the sump tanks 15 and/or storage tanks 25. The additional steel and therefore weight which is installed for sump tanks and storage tanks, is at least partially compensated by a lower number of vertical walls.
In the embodiments discussed hereinabove the invention has been described at the hand of a semi-submersible platform, but it shall be understood that it can be applied as well in other buoyant offshore structures, for example a tension-leg platform, or a spar.
The person skilled in the art will readily understand that, while the invention is illustrated making reference to one or more specific combinations of features and measures, many of those features and measures are functionally independent from other features and measures such that they can be equally or similarly applied independently or in combination in other embodiments of the invention.
This application claims the benefit of U.S. Provisional Application No. 62/270,645, filed Dec. 22, 2015, which is incorporated herein by reference.
Filing Document | Filing Date | Country | Kind |
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PCT/US2016/066787 | 12/15/2016 | WO | 00 |
Number | Date | Country | |
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62270645 | Dec 2015 | US |