The present invention relates to offshore floating platforms, more particularly to a tension leg platform (TLP) for installation in water depths from less than 1,000 to 10,000 ft.
TLPs are floating platforms that are held in place in the ocean by means of vertical structural mooring elements (tendons), which are typically fabricated from high strength, high quality steel tubulars, and include articulated connections on the top and bottom (tendon connectors) that reduce bending moments and stresses in the tendon system. Many factors must be taken into account in designing a TLP to safely transport the TLP to the installation site and keep it safely in place including: (a) limitation of stresses developed in the tendons during extreme storm events and while the TLP is operating in damaged conditions; (b) avoidance of any slackening of tendons and subsequent snap loading or disconnect of tendons as wave troughs and crests pass the TLP hull; (c) allowance for fatigue damage which occurs as a result of the stress cycles in the tendons system throughout its service life; (d) limitation of natural resonance (heave, pitch, roll) motions of the TLP to ensure adequate functional support for personnel, equipment, and risers; (e) maximization of the hydrostatic stability of the TLP during transport and installation; and (e) accommodation of additional requirements allowing for fabrication, transportation, and installation.
These factors have been addressed in the prior art with varying degrees of success. Conventional multi-column TLP's generally have four vertical columns interconnected by pontoons supporting a deck on the upper ends of the vertical columns. Tendons connected at the lower ends of the columns anchor the TLP to the seabed. In such conventional TLP designs, the footprints of the deck, the vertical columns and the tendons are substantially the same and hydrostatic stability of the TLP can be a problem. Some TLP designs address this problem by incorporating pontoons and/or structures that extend outboard of the column(s) to provide a larger tendon footprint to limit natural resonance (heave, pitch, roll) motions of the TLP. In U.S. Pat. No. 6,447,208, a TLP having an extended base substructure is disclosed. Vertical columns supporting a deck on the upper ends thereof form the corners of the substructure. A plurality of wings or arms extends radially out from the outer perimeter of the substructure. The arms increase the radial extension of the base substructure between about 10% and about 100%. The arms include tendon connectors affixed at the distal ends thereof for connection with tendons anchoring the TLP to the seabed. The tendons footprint is substantially larger than the footprint of the substructure.
The present invention, in its various embodiments, addresses the above-described factors to accommodate different payload requirements, various water depths and to improve TLP response. Improvement of TLP performance may be obtained by battering the deck support columns, thereby reducing tendon tension reactions, increasing the free floating stability of the TLP, and reducing overall system costs.
In accordance with a preferred embodiment of the present invention, a tension leg platform includes a deck supported on the upper ends of at least three support columns. The columns are battered inwardly and extend from a base to the deck. Tendons connected at porches extending outwardly from the lower ends of the columns anchor the platform to the seabed. The footprint of the tendons is substantially the same or slightly larger than the footprint of the battered columns, whereas the footprint of the deck is smaller than the footprint of the columns. The battered columns also contribute to platform stability during free floating operations by providing a large water plane dimension at shallow draft.
So that the manner in which the above recited features, advantages and objects of the present invention are attained can be understood in detail, a more particular description of the invention briefly summarized above, may be had by reference to the embodiments thereof which are illustrated in the appended drawings.
It is noted, however, that the appended drawings illustrate only typical embodiments of this invention and are therefore not to be considered limiting of its scope, for the invention may admit to other equally effective embodiments.
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The columns 12 and pontoons 18 form an open structure hull for supporting the deck 16 and the equipment mounted thereon above the water surface 14. The deck 16 is supported above the water surface 14 on the upper ends 26 of the columns 12. The open structure of the columns 12 and pontoons 18 provides improved wave transparency and further defines a moonpool 24 providing access to the seabed from the deck 16. The columns 12 form the corners of the hull and are battered or inclined inwardly toward the central longitudinal axis of the hull. Preferably, the columns 12 are battered inwardly at an angle less than 20 degrees from vertical
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The payload capacity of a TLP system is controlled by the displacement of the structure, as well as the ability of the system to resist overturning moments due to wind, waves, and current. The overturning resistance is lost when a tendon goes slack. For a given displacement and pretension, the overturning resistance is increased by having a larger horizontal plan baseline, i.e., a larger distance between tendons. In a conventional four column TLP, the deck is supported by vertical columns interconnected by pontoons or similar structural members. Consequently, the perimeter dimensions or footprints of the deck and the vertical support columns of a conventional TLP are about equal. The tendon plan dimension is limited to much the same perimeter dimension. The overturning capacity of the TLP is therefore limited by the overall dimensions of the deck and columns. This limitation is overcome by the TLP 10 of the present invention by battering the columns 12 so that the columns 12 footprint, defined by the perimeter dimension of the lower ends 28 of the columns 12, is larger than the deck 16 footprint defined by the perimeter dimension of the upper ends 26 of the columns 12. Also, the battered columns 12 provide an efficient load transfer path for balancing deck weight, hull buoyancy, and tendon tension loads. All loads are direct acting through the columns 12, without large cantilevers or large structural moments. As best shown in
Various modes of transportation may be utilized to transport the TLP or components thereof to the installation site. When the hull and deck are assembled at the fabrication yard, the hull-and-deck assembly may be free floated to the installation site. For free floating conditions of the hull-and-deck assembly (such as deck integration, loading and unloading from a transport vessel, and towing to the installation site), hydrostatic stability is most lacking at shallow draft when the vertical center of gravity of the hull-and-deck assembly is high. The battered columns 12 of the TLP 10 provide a larger water plane dimension at shallower drafts of the free floating hull-and-deck assembly than a conventional TLP with vertical columns. As best illustrated in
The balancing of hydrodynamic loads in waves is another aspect of the design of TLPs, semisubmersibles, and other column/pontoon structures. These platforms are typically optimized with regard to the ratio of volumes of surface piercing structure (vertical columns) and submerged structure (pontoons) in order to minimize the vertical forcing of waves. Under the crest of a wave, the upward force on the surface piercing structure is maximum upward, while the upward force on a submerged structure is maximum downward. Under a wave trough these are reversed. This balance is affected by the draft of the structure and the period of waves. Normally a structure is designed to have the vertical forces balanced and canceling in the most energetic wave periods. For a TLP, these are not the only forces acting, nor the only constraints on geometry, and the final design is a compromise of many factors of which this is one. However, for battered columns, the column begins to have pontoon characteristics with increasing batter. This may be used in the balancing of the structural proportions of the hull in order to provide best performance in waves for a particular site.
As noted above, inclination of the columns 12 imparts pontoon-like properties to the columns 12 which may be best understood by visualizing a horizontal cross section through the columns 12 at the water surface 14 and a shadow (shown in phantom in
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It will be observed that the columns 12 and pontoons 18 are depicted as cylindrical members in the various embodiments of the present invention. However, it is to be understood that the disclosed embodiments are merely exemplary of the invention that may be embodied in various and alternative forms and not intended to be limiting.
While a preferred embodiment of the invention has been shown and described, other and further embodiments of the invention may be devised without departing from the basic scope thereof, and the scope thereof is determined by the claims which follow.
This application is a continuation-in-part application of U.S. application Ser. No. 11/365,505, filed Feb. 28, 2006.
Number | Date | Country | |
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Parent | 11364505 | Feb 2006 | US |
Child | 12255579 | US |