Very large floating structure

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Very large floating structures (VLFSs) or very large floating platforms (VLFPs) are manmade islands, which may be constructed to create floating airports, bridges, breakwaters, piers and docks, storage facilities (for oil & natural gas), wind and solar power plants, for military purposes, to create industrial space, emergency bases, entertainment facilities (such as casinos), recreation parks, mobile offshore structures and even for habitation. Currently, several different concepts have been proposed for building floating cities or huge living complexes.[1] Some units have been constructed and are presently in operation.[2]

Floating structures offer several advantages over more permanent structures which might extend from the shore into open water:

  • they do not damage the marine eco-system;
  • they do not cause silt deposition in deep harbors;
  • they do not disrupt the ocean currents;
  • they are easy to construct, since much of the construction is completed onshore;
  • installation is rapid;
  • they are immune to seismic shock.[3]


VLFS differ from watercraft in that the usable area is the top surface instead of the internal (hold) areas. Thus a useful VLFS will cover significant area. It can be constructed by joining the necessary number of floating units together. The design of the floating structure must comport with safety and strength requirements, operating conditions, etc. Steel, concrete (prestressed or reinforced hybrid) or steel-concrete composite materials may be used to build the floating structure. The motion of the floating structure due to wind or wave action must be substantially neutralized, to ensure the safety of people and facilities on a VLFS, and to allow useful activities. VLFS must be securely moored to the ocean bed.[4]


Current designs for VLFS fall into two categories: semi-submersible, and pontoon.

The semi-submersible-type VLFS has a raised platform above sea level using column tubes; it is more suitable for deployment in high seas with large waves. In open sea, where the waves are relatively large, the semi-submersible VLFS minimizes the effects of waves while maintaining a constant buoyant force. Semi-submersible types are used for petroleum exploration in deep waters. They are fixed in place by column tubes, piles, or other bracing systems.

The pontoon-type VLFS platform rests on the water surface and is intended for deployment in calm waters such as a cove, a lagoon or a harbor. Its basic element is a simple box structure; it usually offers high stability, low manufacturing cost and easy maintenance and repair. The pontoon type is supported by its buoyancy on the sea surface. The pontoon type is flexible compared to other kinds of offshore structures, so that the elastic deformations are more important than their rigid body motions. Thus, hydroelastic analysis is uppermost in designing the pontoon-type VLFS. Together with the motion of the floating structure, the response of the structure to water waves and the impact on the entire fluid domain have to be studied.

VLFS types

Pontoon-type VLFS are also known in the literature as mat-like VLFS because of their small draft in relation to the length dimensions. Very large pontoon-type floating structures are often called Mega-Floats. As a rule, the Mega-Float is a floating structure having at least one length dimension greater than 60 meters. Horizontally large floating structures can be from 500 to 5000 meters in length and 100 to 1000 meters in width, with typical thickness of 2 to 10 meters.

Air-cushion supported Mega-Floaters are mega floaters that are supported by an air cushion. They were invented by Jan Van Kessel of TU Delft.[5]


Many large floating structures have been conceptualized, including a golf course,[6] a farm,[7] and habitable long-term living complexes (seasteading).

Some large floating structures that have been built include floating airports and floating landing platforms for returning rockets.

Floating airport

As of 2002, the largest offshore structure built is the Mega-Float, a floating airport prototype that was constructed in Tokyo Bay from 1998 to 1999.[8] It is one kilometer in length, and was primarily intended as a test vehicle, to research the loadings and responses of such installations.[9] This project was substituted as a study project to provide more definite information about a proposed floating runway at Kansai International Airport, which was not built (an artificial island was instead constructed to support the runway).

Floating landing platforms

As of October 2014, Space Exploration Technologies (SpaceX) has contracted with a Louisiana shipyard to build a floating landing platform for reusable orbital launch vehicles. The initial platform has an approximately 90 by 50 meters (300 ft × 160 ft) landing pad surface and is capable of precision positioning with diesel-powered Azimuth thrusters[10] so the platform can hold its position for launch vehicle landing. This platform was first deployed in January 2015[11] when SpaceX attempted a controlled descent flight test to land the first stage of Falcon 9 Flight 14 on a solid surface after it was used to loft a contracted payload toward Earth orbit.[12][13] The platform utilizes GPS position information to navigate and hold its precise position.[14] The rocket landing leg span is 18 m (60 ft) and must not only land within the 52 m (170 ft)-wide barge deck, but must also deal with ocean swells and GPS errors. SpaceX has projected that the likelihood of successfully landing on the platform on the first try is 50 percent or less.[15]

SpaceX CEO Elon Musk displayed a photograph of the "autonomous spaceport drone ship" in November 2014. The ship is designed to hold position to within 3 meters (9.8 ft), even under storm conditions.[16]

Floating LNG production facility

The Shell floating LNG plant is under construction to process and liquify offshore natural gas into liquified natural gas for transport and storage.[17] The Shell project is scheduled to begin processing gas in 2016.[18]

See also


  1. "DeltaSync floating city". Retrieved 27 October 2014.<templatestyles src="Module:Citation/CS1/styles.css"></templatestyles>
  2. Japan constructed the Mega-Float (a floating runway in Tokyo bay); Japan also has floating fuel storage bases at Shirashima and Kamigoto Islands, and floating ferry piers at Ujina port (Hiroshima). Several very long floating bridges are currently in use; three are located near Seattle, Washington USA. The Floating Bridge, Dubai, over the Dubai Creek, is 300 meters long. Singapore built the world’s largest floating performance stage at the Marina Bay, and is currently installing a mega floating fuel storage facility off Pulau Sebarok. South Korea is currently installing three floating islands on the Han River, to be used for convention centers, and another project at Seoul will function as hotel/convention center/customs site/quay. Science Direct, Very Large Floating Structures, p. 63
  3. [1] p. 63
  4. [2] "Drift forces for mooring system design - The design of a mooring system requires the determination of wave drift forces acting on the VLFS." p. 67
  5. "Jan Van Kessel's mega-floater design". Retrieved 27 October 2014.<templatestyles src="Module:Citation/CS1/styles.css"></templatestyles>
  6. Kiniry, Laura. "9 of the World's Weirdest Floating Structures: floating golf course". Retrieved 28 October 2014.<templatestyles src="Module:Citation/CS1/styles.css"></templatestyles>
  7. Kiniry, Laura. "9 of the World's Weirdest Floating Structures: floating farm". Retrieved 28 October 2014.<templatestyles src="Module:Citation/CS1/styles.css"></templatestyles>
  8. Very large floating structure — Mega-Float, completed 1999. New Atlantis 2002, retrieved 01 October 2011
  9. Areas being studied in Mega-Float include the hydroelastic behavior of the unit, the mooring system response and durability, the connector system and its welded joints, the anti-corrosion system, the unit's effect on the surrounding seawaves which impact the nearby shoreline, and the unit's effect on the bay's prevailing currents, water quality and marine ecosystems.
  10. "SpaceX Announces Spaceport Barge Positioned by Thrustmaster's Thrusters". Thrustmaster. 22 November 2014. Retrieved 23 November 2014.<templatestyles src="Module:Citation/CS1/styles.css"></templatestyles>
  11. Bergin, Chris (17 December 2014). "SpaceX confirms CRS-5 launch slip to 6 January". Retrieved 18 December 2014.<templatestyles src="Module:Citation/CS1/styles.css"></templatestyles>
  12. Foust, Jeff (25 October 2014). "Next Falcon 9 Launch Could See First-stage Platform Landing". Space News. Retrieved 25 October 2014.<templatestyles src="Module:Citation/CS1/styles.css"></templatestyles>
  13. Bullis, Kevin (25 October 2014). "SpaceX Plans to Start Reusing Rockets Next Year". MIT Technology Review. Retrieved 26 October 2014.<templatestyles src="Module:Citation/CS1/styles.css"></templatestyles>
  14. Dean, James (24 October 2014). "SpaceX to attempt Falcon 9 booster landing on floating platform". Retrieved 27 October 2014.<templatestyles src="Module:Citation/CS1/styles.css"></templatestyles>
  15. Bergin, Chris (18 November 2014). "Pad 39A – SpaceX laying the groundwork for Falcon Heavy debut". NASA Spaceflight. Retrieved 17 November 2014.<templatestyles src="Module:Citation/CS1/styles.css"></templatestyles>
  16. Musk, Elon (22 November 2014). "Autonomous spaceport drone ship". SpaceX. Retrieved 23 November 2014.<templatestyles src="Module:Citation/CS1/styles.css"></templatestyles>
  17. "Shell floating LNG technology chosen by joint venture for Greater Sunrise project - Shell Worldwide". Retrieved 10 June 2011.<templatestyles src="Module:Citation/CS1/styles.css"></templatestyles>
  18. Kelly, Ross (19 June 2014). "GDF Suez, Santos Halt Innovative LNG Plan in Australia: Companies Say Offshore Conversion Project Not Commercially Viable". Wall Street Journal. Retrieved 30 December 2014. The decision highlights the risks confronting Australian gas-export projects as they grapple with high costs and competition from North America and Russia, which are vying to provide Asian utilities with cleaner-burning fuels. Confidence in "floating" liquefied natural gas may also be diminishing—two years before a Royal Dutch Shell PLC-owned vessel is due to begin processing gas for the first time.<templatestyles src="Module:Citation/CS1/styles.css"></templatestyles>

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