A method for manufacturing a floating foundation for a wind turbine, wherein the floating foundation comprises load carrying structures and a plurality of air pontoons attached to the load carrying structures, is disclosed. The method includes cutting one or more fiber-reinforced composite structures, such as wind turbine blades, into a plurality of smaller pieces comprising fiber-reinforced composite, molding the air pontoons from the smaller pieces, and attaching the air pontoons to the load carrying structures.

This document describes an offshore power generating system comprising a T-shaped hub connected to propeller blades and generators on a common shaft in a generator housing. The hub transfers the variable torque of the respective propeller blades, with flaps to a common shaft where generators are connected by means of couplings.

A base supporting an offshore wind power generator includes a fender portion composed of a pair of cylindrically shaped first fender portion and second fender portion for cushioning an impact when a ship touches the fender portion, and rung portions extending horizontally from the fender portion toward the base and composed of first rung portions and second rung portions installed at predetermined intervals in the vertical direction. A worker on board the ship can safely transfer to the adjacent rung portions when the hull of the ship kept touching the fender portion.

An off-shore wind turbine system is assembled using a platform or jack-up vessel, and a first base anchored to the seafloor at a blade assembly off-shore location. A buoyant tower is attached to the first base. A crane provided on the platform or jack-up vessel is used to lift blades and blades, which are then coupled to a turbine held in a nacelle provided at the top of the buoyant tower. The buoyant tower, the nacelle, and the blades are detached from the first base. The buoyant tower, the nacelle, and the blades are towed to a wind farm and connected to a second base provided in the wind farm. The buoyant tower, the nacelle, and the blades are further stabilized using mooring lines spanning between the buoyant towers and other bases provided in the wind farm. The first base and/or the second base include anti-rotation features.

A semi-submersible wind power platform includes a tower and a plurality of arms for stabilizing the tower, each arm having a float experiencing an anchoring force. Each arm consists of two elongated elements forming with part of the tower a triangle, and at least one of the elongated elements includes a catenary element.

A mooring system for mooring a floating platform having a plurality of stabilizing arms with floats, the mooring system including an anchoring system containing a plurality of anchors and anchoring cables for anchoring the mooring system in deep sea. The center part of the mooring system includes a mooring unit containing a plurality of mooring elements and positioning wires, where each mooring element is connected to an adjacent mooring element with a positioning wire and to an anchor.

A system, an arrangement and a method, all for motion damping of a floating marine structure. Also disclosed is a use of the system. The system has at least one dampening device configured to dampen a movement in one direction and allowing a movement in the opposite direction, and a suspension arrangement has a respective wire configured to suspend the at least one dampening device hanging at a suspended depth in the water from the marine structure and with the dampening device oriented so that a dampening force induced by the dampening device is subjected in the extension of the wire. Also, each dampening device is a passive damping device has a valve structure configured to dampen a movement in one direction and allowing a movement in the opposite direction essentially without damping interaction.

The present invention relates to a vertical axis wind turbine equipped with a high-temperature superconducting generator having a batch impregnation cooling structure.

The vertical axis wind turbine is configured to allow the superconducting generator and accessory devices (a cooling system, a power conversion system, etc.) to be located under a turbine tower, whereas allowing only a rotary body with vertical blades to be located on the upper portion of the turbine tower, unlike a conventional horizontal axis wind turbine, thereby remarkably reducing a top-head weight of the wind turbine, greatly decreasing installation and maintenance costs, removing technical difficulties in large scale construction, and allowing a center of weight to move to a portion under the turbine tower so that if the vertical axis wind turbine is applied for floating offshore wind power generation, it advantageously ensures the miniaturization of a floating body and the stability of a floating posture.

An apparatus for converting mechanical energy from wind to fluid-fuel energy is an offshore wind-turbine apparatus. Electrical energy generated by the turbine is used in an electrolysis process to convert sea water to fluid fuel. The fuel may be stored in tanks beneath the water surface or on the ocean floor.

A mooring line that provides substantially constant force, also referred to a mooring line that is always soft, allows the orbital motion of a moored turbine structure under varying wave conditions and is suitable for storm conditions when the turbine is not operating. A mooring line with substantially constant force does not create surge acceleration from heave acceleration and does not cause the turbine structure to be pulled through the water relative to orbital velocity.