A flotation system for an offshore power generation platform comprises: multiple buoyant bodies each containing a high-pressure air and ballast water therein to create buoyancy; connecting members connecting the multiple buoyant bodies to each other; ballast water flowing tubes through which the ballast water contained in the multiple buoyant bodies flows with respect to each other; a high-pressure tank supplying the high-pressure air into the multiple buoyant bodies; a compressor replenishing air pressure present in the high-pressure tank; an equilibrium sensor sensing an equilibrium state of each of the multiple buoyant bodies and transmitting a signal; and a controller controlling, in response to the signal from the equilibrium sensor, an amount of air supplied from the high-pressure tank to the buoyant body and an amount of air discharged from the buoyant body.

A marine vessel (10) includes: a hull (11); an electric propulsion portion (15) that propels the hull (11); a water tank portion (20) that is provided on the hull (11) and is capable of storing water in the water tank portion; a float portion (40) that is provided within the water tank portion (20) so as to be movable upward and downward; and a battery case (30) that is attached to the float portion (40) and is capable of storing a detachable portable battery (35) which becomes an electric power source of the electric propulsion portion (15) in the battery case.

A marine vessel (10) includes: a hull (11); an electric propulsion portion (15) that propels the hull (11); a water tank portion (20) that is provided on the hull (11) and is capable of storing water in the water tank portion; a float portion (40) that is provided within the water tank portion (20) so as to be movable upward and downward; and a battery case (30) that is attached to the float portion (40) and is capable of storing a detachable portable battery (35) which becomes an electric power source of the electric propulsion portion (15) in the battery case.

A method lowers a hollow structure through water and installs that structure at a subsea location. The structure has an internal space containing a ballast material such as sea salt that is substantially denser than water. Upon being lowered with the aid of the ballast material to a subsea destination, the structure is anchored at that destination. Then, water is introduced into the internal space to dissolve, suspend or dilute the ballast material. Thus dissolved, suspended or diluted, the ballast material is evacuated or dispersed from the internal space in a liquid or fluidized form. For example, a solution or suspension of the ballast material can be entrained in a flushing flow of water through and from the internal space. The internal space is then available to perform another, primary function in subsea operation of the structure, for example as a flowline to convey oil or gas.

An object of the present invention is to provide a float assembly that can prevent the floats from flipping. The present invention provides a float assembly including a plurality of floats connected together comprising: a filled float having a hollow portion, wherein the hollow portion has a part filled with a filler, and the filled float is arranged at a position facing an assembly periphery surrounding the float assembly.

The present disclosure provides apparatus and methods that improves the speed, functionality, and safety of wakeboat ballasting operations. A ballasting apparatus for wakeboats is provided, comprising a wakeboat with a hull and an engine; a hydraulic pump, mechanically driven by the engine; a hydraulic motor, powered by the hydraulic pump; a ballast compartment; and a ballast pump, powered by the hydraulic motor. A ballasting apparatus for wakeboats is provided, comprising a wakeboat with a hull and an engine; a ballast compartment; and a hydraulic ballast pump, the ballast pump configured to be powered by the engine, the ballast outlet and/or inlet of the ballast pump connected to the ballast compartment, the ballast pump configured to pump ballast in and/or out of the ballast compartment. A ballast pump priming system for wakeboats is provided, comprising a wakeboat with a hull and an engine; a ballast pump on the wakeboat; a fitting on the ballast pump which permits water to be introduced into the housing of the ballast pump; and a source of pressurized water, the pressurized water being fluidly connected to the fitting, the pressurized water thus flowing into the housing of the ballast pump.

To be able to improve the flexibility in handling containers, a container ship configured to transport containers includes: an opening 106 through which cargo may be handled by moving a wheeled platform 501 between the container ship and a dock, the wheeled platform 501 including a plurality of containers 401 placed thereon; and a floor board 108 or a rail configured to support the wheeled platform 501 loaded from the dock through the opening 106.

To be able to improve the flexibility in handling containers, a container ship configured to transport containers includes: an opening 106 through which cargo may be handled by moving a wheeled platform 501 between the container ship and a dock, the wheeled platform 501 including a plurality of containers 401 placed thereon; and a floor board 108 or a rail configured to support the wheeled platform 501 loaded from the dock through the opening 106.

An automatic wing control mechanism for sailing vessels is described. The automatic wing control mechanism adjusts a wing orientation with respect to the apparent wind to optimize its efficiency.

An automatic wing control mechanism for sailing vessels is described. The automatic wing control mechanism adjusts a wing orientation with respect to the apparent wind to optimize its efficiency.