Various embodiments of a submerged submersible sailing vessel are disclosed. Such a submerged sailing vessel may comprise a submersible hull assembly, a keel coupled to and extending upwards from hull assembly towards a water surface, and a wind-catching assembly coupled to and extending upwards into the air from the keel for propelling the submerged sailing vessel. The hull assembly and the keel are submerged below the water surface as the vessel is propelled by the wind-catching assembly above the water surface.

A system is demonstrated for heave neutralisation of semisubmersible platforms that can be built into any conceivable configuration of such platforms. That the system is also conceivably active and predicatively can be controlled can be concluded by analysing the appended calculation models. As an example FIG. 18, column E, is mentioned, wherein the water volume increments in the rise canister are 37 cubic metres for each half metre of wave height, so that, with reference to column A, from H=10.5 m to H=12 m is 4×37 148 cubic metres more than 150 tonnes—simultaneously with the air pressure, shown in column K, increasing from 123.86 to 131.05 kPa, a difference of just 6.19 kPa (0.0619 bar or 61.9 millibars). Large ballast volumes can be moved out and in of the system at small pressure changes and short response time.

A floating platform for high-power wind turbines, comprising a concrete substructure, said concrete substructure forming the base of the platform, which remains semi-submerged in the operating position, and consisting of a square lower slab on which a series of beams and five hollow reinforced concrete cylinders are constructed, distributed at the corners and the center of said lower slab; a metal superstructure supported on the concrete substructure and forming the base for connection with the wind turbine tower, said tower being coupled at the center thereof; and metal covers covering each of the cylinders, on which the metal superstructure is supported and to which vertical pillars are secured, linked together by beams, which join at the central pillar by an element whereon the base of the wind turbine tower is secured.

A mobile farm for the growth of hydrobiological species, capable of offshore operation, which maintains a shoal-like behaviour of the fish confined therein, and being of robust design and construction. The use of related materials enables the structure to remain afloat, anchored, moored to a buoy or in movement, either self-propelled, towed or pushed. Formed by a central structure similar to a ship's hull, its hydrodynamic bow enables it to cut through the waves with minimum resistance, reinforced by a perimetral support; these combine with the use of heavyweight metallic meshes, thus constituting a floating means suited for offshore operation, with the ability to alter its draught and hydrodynamic presentation, consequently changing the containment volume of the species by means of a system for the individual or collective hoisting of the containment meshes.

An offshore semi-submersible platform includes: at least three stabilizing columns; a truss structure securing the at least three stabilizing columns to one another; for at least one of the stabilizing columns, a substantially horizontal perforated plate and a fastening arranged for fastening the substantially horizontal perforated plate to the stabilizing column at least in a working position below a bottom surface of the stabilizing column, creating a wave load attenuation chamber being defined between the substantially horizontal perforated plate in the working position and the bottom surface of the stabilizing column.

A system for conveying a fluid produced from at least one producing subsea well to an existing host facility via a flowline includes a support structure having at least a deck, a mooring system, and a plurality of topsides modules. The mooring system anchors the support structure to a seabed and passively positions the support structure proximate to the at least one producing subsea well. The support structure elevates the deck above a water's surface and is normally unmanned. The plurality of topsides modules are disposed on the deck. The topsides modules include at least: a power generation module; a switchgear module a flowline heating module; a chemical injection module; a water injection module; a subsea control module; and a control module that communicates with a remote command center.

A semi-submersible crane vessel for use in assembling a wind turbine and for installation by means of a crane of the vessel of the assembled wind turbine on a foundation. At an assembly station, the hull of the vessel is provided with a mast-receiving well that is sunk into, or through, the hull, preferably a well that extends into, or through a support column of the hull, which well is configured to receive therein at least a portion of the mast of the wind turbine during an assembly step of the wind turbine. For example, the mast-receiving well has a depth of at least 15 meters, e.g. at least 30 meters, measured from the deck of the deckbox structure.

The present invention relates to a method for installing an offshore wind turbine at a target location at sea with an installation vessel, the vessel comprising:—a nacelle support structure for temporarily supporting a nacelle comprising a hub having a plurality of root end connectors to which the root ends of the blades are to be connected, the nacelle support structure comprising:—a support tower extending upwardly from a deck of the installation vessel,—a support platform configured to temporarily support the nacelle,—one or more lifting devices configured for:—lifting the nacelle onto the support platform,—lifting a nacelle assembly including the blades onto a wind turbine mast located adjacent the vessel, wherein the method comprises: a) lifting the nacelle onto the support platform, and securing the nacelle to the support platform, b) orienting a root end connector of the hub of the nacelle in a direction facing a guide path of the blade moving system, c) connecting the root end of the first blade to the corresponding first root end connector of the hub, d) repeating steps b) and c) for subsequent blades and root end connectors until all blades are connected to the hub of the nacelle, thereby providing a RNA, e) lifting the RNA from the nacelle support structure and positioning the RNA onto a wind turbine mast located adjacent the vessel.

A floating offshore structure includes a buoyant hull including a first column, a second column, and a pontoon coupled to the first column and the second column. The pontoon extends horizontally from the first column to the second column. The pontoon includes a first tubular member, a second tubular member positioned laterally adjacent to the first tubular member, a first edge plate extending horizontally from the first tubular member, and a second edge plate extending horizontally from the second tubular member. The first tubular member and the second tubular member are disposed between the first edge plate and the second edge plate. Each tubular member has a central axis, a first end coupled to the lower end of the first column, and a second end coupled to the lower end of the second column. The longitudinal axis of the first tubular member and the longitudinal axis of the second tubular member are disposed in a common horizontal plane.

A hydrofoil device for a mobile offshore apparatus, in particular, a watercraft. The hydrofoil device includes at least one base body with at least one connection unit which is arranged for connecting the hydrofoil device to the mobile offshore apparatus. At least one hydrofoil is arranged on the base body. At least one flow generator is arranged to generate a flow around the hydrofoil. The hydrofoil device in its intended use is rotatable at least about a substantially vertical axis of rotation depending on at least one control data set that can be provided.