NO332002B1 - Floating platform and method for increasing the payload capacity of the floating platform - Google Patents

Abstract

A floating platform for extracting oil and gas from offshore oil and gas fields includes a hull with a portion located substantially below the water surface, and includes a portion thereof extending over the water surface. The platform is anchored to the seabed by one or more tension bars attached to the foundation of the hull and seabed. The payload capacity of the floating platform is increased without reconstructing the structural design of the hull by attaching a column extension or mounting a disconnected optical module to the lower end of the hull to facilitate change of the platform payload requirement.

Description

BACKGROUND FOR THE DESCRIPTION

The present invention generally relates to floating platform systems for testing and producing hydrocarbon formations found in deep (600-10,000 feet) offshore areas. More precisely, the invention relates to a method and a system for changing the buoyancy of the floating platform to facilitate changes in the platform's payload and water depth requirements without reconstructing the platform hull.

NO 314719 B1 concerns a floating offshore platform for oil operations in deep water. A lower part of the hull is connected to an upper part of the hull by a telescoping mechanism. The telescopic relationship between the hull parts has the property that the buoyancy and immersion can be regulated according to the operating mode the platform is in.

GB 1488065 deals with a method of installing a floating platform at sea. The installation involves the use of temporary buoyancy elements that can be connected to the platform's side and underside during installation to ensure the desired dive.

US 5964550 describes a tie rod anchoring system including a production platform that stores one or more decks above the water surface to store equipment for processing oil, gas and water extracted from an underwater hydrocarbon formation. The deck or decks are arranged on a column which is formed by one or more buoyancy tanks located below the water surface. The columns include a foundation structure comprising three or more pontoons extending outward from the base of the column.

Extraction of oil and gas deposits in offshore areas, and recovery of oil and gas from there, is very expensive. Large capital expenditure is required and thus only large oil and gas deposits justify such expenditure. Smaller oil and gas deposits usually do not justify large capital investments and are therefore considered uneconomical to produce.

Various methods and offshore production systems have been used to locate and recover offshore oil and gas deposits. Production systems such as converted mobile offshore drilling units ("MODU") and tie rod platforms (TLP) are typically used in deeper water. However, even these systems can be quite expensive to manufacture and install.

There is still a need for improved platform and drilling systems, especially for use in deep water, that will justify the financial investment to produce even relatively small oil and gas fields. Drilling and production platforms, such as TLPs are designed for use in special offshore environments and to carry a maximum payload. Specifications for the Platform are based on assumptions that may or may not be accurate once the Platform is installed and in use for a period of time. Other factors, such as the recovery of recoverable oil and gas from adjacent deposits can change the payload requirements for a platform that is already in use. Thus, being able to increase the payload that a platform can carry without reconstructing the hull will be highly desirable and significantly reduce the cost of producing offshore oil and gas deposits. The cost reduction can also be achieved by eliminating the need for a complete redesign of the hull and node in the construction of the platform to accommodate different payload requirements. The buoyancy of a floating platform can be increased by extending the column length of the platform instead of redesigning the hull, thereby saving time and construction costs associated with redesigning the platform hull.

It is therefore an object of the present invention to provide a floating platform adapted to carry an increase in payload capacity without redesigning the structural design of the hull of the platform. The increase in payload capacity is facilitated by attaching a column that extends to the lower end hull of the platform while it is in the manufacturing yard.

Another object of the present invention provides a floating platform whereby the payload capacity of the platform can be increased after the platform is located in the field. Such an increase in payload capacity is provided by attaching a buoyancy module to the platform hull instead of redesigning the hull and node construction of the platform.

SUMMARY OF THE INVENTION

The objectives of the present invention are achieved by a floating platform comprising a hull which stores one or more tires in a body of water above the waterline, anchor device which attaches the hull to the seabed, said hull includes a buoyancy device for storing said one or more tires to said platform above the waterline and pontoons attached to a lower end of said hull; characterized by supplementary buoyancy devices releasably mounted on said hull below the pontoons to increase the buoyancy of said platform.

Preferred embodiments of the platform are detailed in claims 2 to 6 inclusive.

The objectives of the present invention are also achieved by a method for increasing the usable space capacity of a floating platform without reconstructing the structural design of the hull of said platform, characterized in that the method includes the step of releasably attaching a supplementary buoyancy device arranged under pontoons attached to a lower end of the hull of said platform.

The present invention provides a floating platform for the extraction of oil and gas from offshore oil and gas fields. The platform carries one or more decks above the surface of the water to accommodate the equipment for drilling and processing oil, gas and water extracted from oil and gas fields. The platform may include a hull with a portion located substantially below the water surface, and includes a portion extending above the water surface. The platform hull includes a foundation and is anchored to the seabed by one or more tension rods attached to the foundation of the hull at one end thereof and to the seabed at the opposite ends of the tension rods. The payload carrying capacity of the platform has been increased without reconstructing the structural design of the platform hull by attaching a pillar extension to the bottom of the platform hull.

BRIEF DESCRIPTION OF THE DRAWINGS

In order that the manner in which the above-mentioned properties, advantages and objectives of the present invention have been achieved is to be understood in detail, a more specific description of the invention can be briefly summarized above, with reference to the execution thereof which is illustrated in the attached drawings.

It should, however, be noted that the attached drawings only reduce typical embodiments of this invention and are therefore not considered to limit its scope, as the invention can make room for other equally effective embodiments. Fig. 1 is a side view of a floating platform anchored to the seabed; Fig. 2 is a side view of the floating platform of the invention including a buoyancy extension attached to the bottom of the hull of the platform; Fig. 3 is a partial side view of an alternative embodiment of the platform of the invention showing a buoyancy module mounted to the bottom of the hull of the platform; Fig. 4 is a top view of the platform of the invention shown in fig. 3; Fig. 5 is a partial exploded view of the coupling device for attaching the buoyancy module of the invention to the hull of the platform; and Fig. 6 is a side view of the platform of the invention illustrating the riser or flow line storage device mounted to the buoyancy module of the invention.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENT

With reference first to fig. 1, the floating platform of the invention is generally identified by the reference numeral 10. The platform 10 includes a center column or hull 12 which provides positive buoyancy and vertical support for the platform 10. One or more decks 14 are supported on the hull 12 above the water surface 16. Drill - and/or production equipment necessary for the extraction and treatment of oil, gas and water extracted from the oil and gas field is attached to the deck 14.

The hull 12 extends upwards from the foundation or keel of the hull 12. The foundation node of the hull 12 includes pontoons 18 which extend radially outward from the hull 12. The platform 10 is anchored to the seabed by tie rods 20 attached at one end thereof to the pontoons 18 and at the opposite ends thereof to foundation piles (not shown in the drawings) submerged in the seabed. The hull 12 provides sufficient buoyancy to store the payload to the platform 10, which payload includes the deck 14, drilling and/or completion equipment, production facilities, production and drilling risers and sufficient excess buoyancy to develop pre-tensioning of tension rods.

The platform 10 is designed for the environmental and depth conditions at the offshore site of an oil and gas deposit of interest. At other locations, other platforms may be required to efficiently extract oil and gas from other subsea deposits. Such other platforms may be required to carry a larger payload than the platform 10 is designed to carry. However, the increased payload can be accommodated by increasing the buoyancy of the platform 10. An increase in buoyancy can be accomplished by extending the length of the hull 12 instead of reconstructing the structural design of the hull and foundation node construction of the platform 10. Likewise, the payload requirements for a platform can increase after installation, in which case the buoyancy module 32, as shown in fig. 3, may be mounted to the bottom of the hull 12 of the platform 10.

Now with reference to FIG. 2, the column extension 22 is a relatively short cylindrical chamber with an outside diameter approximately equal to the outside diameter of the hull 12. The column extension 22 is welded to the bottom of the hull 12 by weld 23 at the manufacturing or construction site of the platform 10.

Now with reference to FIG. 3 shows an alternative embodiment of the invention, a buoyancy module 32 mounted to the bottom of the hull 12.1 the embodiment in fig. 3, the buoyancy module 32 is added to the offshore platform 10 as it is located on the field, to increase the payload capacity of the platform 10, so that additional equipment can be installed on the deck of the platform 10 or so that the platform 10 can be installed in a deeper location. The buoyancy module 32, as the column extension 22 shown in fig. 2, is a relatively short cylindrical chamber with a diameter approximately equal to the diameter of the hull 12. Mounting posts 24 attach the module 32 to the hull 12. Mounting posts 24 may be welded or otherwise attached to the hull 12 and the module 32.

Alternatively, the mounting posts 24 can be pre-installed around the periphery of the hull 12 by welding or other connecting devices, so that the module 32 can be installed at a later time after the platform 10 is anchored offshore, as required, to increase the payload capacity of the platform 10. The buoyancy module 32, shown in fig. 3, is likewise provided with mounting posts 26 for cooperative engagement with posts 24 mounted on the hull 12. As is more clearly shown in fig. 5, the mounting posts 24 are adapted to be received or telescoped into the posts 26. Various connecting means, such as cement slurry, mechanical couplings or welding, can be used to lock the posts 24 and 26 together and thus attach the buoyancy module 32 to the bottom of the hull 12. - method has the added benefit of allowing the module 32 to be more easily disconnected from the hull 12 in the event that the payload requirements of the platform 10 change and the buoyancy module

32 is no longer needed or to replace a larger module in the event that greater buoyancy is required. Two or more modules 32 can also be connected in an extra-anchor manner in a vertical arrangement with the hull 12 in the event that further buoyancy is required.

The column extension 22 and the buoyancy module 32 can be provided with the necessary pipes, including a fill port 28 and ventilation 30, for connection with the ballast system of the platform 10. Additional riser hangers, such as portals 33, for hanging risers or flow lines 34 therefrom, as shown in fig . 6, may be installed on the column extension 22 or module 32, as required.

The shape of column extension 22 and module 32 is shown as a closed cylinder or plug for illustrative purposes. It should be understood that the extension 22 and the module 32 can have different designs. If, for example, the hull 12 includes a lower deck opening (English moon pool), the extension 22 and the module 32 can be arranged with an axial passage for matching device with the profile of the lower deck opening. The extension 22 and the module 32 in such an arrangement will have a shape or profile similar to a doughnut. Likewise, the extension 22 and the module 32 may include radial extensions or arms that match the profile of the pontoon 18, which arms may be attached to the bottom of the pontoons 18.

Since one or more preferred embodiments of the invention have been shown and described, other and further embodiments of the invention can be indicated without deviating from the main scope thereof, and the scope thereof is limited by the claims that follow.

Claims (7)

1. Floating platform (10) comprising a hull (12) which stores one or more tires (14) in a body of water above the waterline, anchor device which attaches the hull (12) to the seabed, said hull (12) includes buoyancy device to store said one or more decks (14) of said platform (10) above the waterline and pontoons (18) attached to a lower end of said hull (12); characterized by supplementary buoyancy devices (22, 23) releasably mounted on said hull (12) below the pontoons to increase the buoyancy of said platform (10). 2. Platform (10) according to claim 1, characterized in that said supplementary buoyancy device comprises a column extension (22) mounted on a lower end of said hull (12). 3. Platform (10) according to claim 2, characterized in that said column extension (22) includes piping for connection with the ballast system of said floating platform (10). 4. Platform (10) according to claim 1, characterized in that said supplementary buoyancy device comprises at least one buoyancy module (32) mounted on said hull (12). 5. Platform (10) according to claim 4, characterized in that it includes couplings which releasably attach said buoyancy module (32) to said hull (12). 6. Platform (10) according to claim 1, characterized in that said supplementary buoyancy device includes support device on a peripheral surface thereof for storage of one or more riser pipes or flow lines (34) connected to said platform (10). 7. Method for increasing the payload capacity of the floating platform (10) without reconstructing the structural design of the hull (12) of said platform (10), characterized by the method comprises the step of releasable attachment of supplementary buoyancy device (18) arranged under pontoons (18) attached to a lower end of the hull (12) of said platform (10).