A portable, pumpless water ballast system can be constructed of a flexible water-proof membrane molded or formed of welded panels to make a desired shape, such as cube-shaped when filled with water. Along the top side is an opening for filling the container. A water-proof closure is provided in the opening to prevent water leaking out. An air release valve can be installed near the top area of the container's top or side panels. A handle or strap can also be provided on one or more of the adjacent sides of the container. A plastic threaded drain and closure can be provided on one or more sides to allow for emptying of the container or to attach other features like a hose or other accessory.

The present disclosure provides hydraulic power sources for watercraft. Example power sources can include: a watercraft having an engine; a variable ratio drive assembly operably engaged with the engine; a hydraulic pump operably engaged with the variable ratio drive assembly; and a hydraulic motor powered by the hydraulic pump. The present disclosure also provides methods for providing hydraulic power aboard a watercraft. Example methods can include: using an engine of the watercraft to drive a variable ratio drive assembly; using the variable ratio drive assembly to drive a hydraulic pump; using the hydraulic pump to power a hydraulic motor; and using the hydraulic motor to drive a load.

The present disclosure provides hydraulic power sources for watercraft. Example power sources can include: a watercraft having an engine; a variable ratio drive assembly operably engaged with the engine; a hydraulic pump operably engaged with the variable ratio drive assembly; and a hydraulic motor powered by the hydraulic pump. The present disclosure also provides methods for providing hydraulic power aboard a watercraft. Example methods can include: using an engine of the watercraft to drive a variable ratio drive assembly; using the variable ratio drive assembly to drive a hydraulic pump; using the hydraulic pump to power a hydraulic motor; and using the hydraulic motor to drive a load.

A wakeboat includes a hull; a thruster associated with the hull of the wakeboat, the thruster configured to selectively impart lateral force to the hull; an operator control in the wakeboat configured to control a parameter of the wakeboat other than the thruster; a thruster control associated with the operator control, the thruster control selectively receiving input from the operator to control the thruster, the thruster control positioned to be operable with at least the same hand and/or fingers already operating the operator control. Other systems and methods for controlling a wakeboat are also provided.

A wakeboat includes a hull; a thruster associated with the hull of the wakeboat, the thruster configured to selectively impart lateral force to the hull; an operator control in the wakeboat configured to control a parameter of the wakeboat other than the thruster; a thruster control associated with the operator control, the thruster control selectively receiving input from the operator to control the thruster, the thruster control positioned to be operable with at least the same hand and/or fingers already operating the operator control. Other systems and methods for controlling a wakeboat are also provided.

The present disclosure provides power source assemblies aboard a watercraft. The power source assemblies can include: an engine having a crankshaft; a variable ratio drive assembly operably engaged with the crankshaft; and an engine powered accessory operably engaged with the variable ratio drive assembly. The present disclosure also provides methods for distributing power aboard a watercraft from a crankshaft of an engine. The methods can include: using a crankshaft of an engine to drive a variable ratio drive assembly; and using the variable ratio drive assembly to drive an engine accessory over a narrower RPM range while operating the crankshaft over a wider RPM range.

The present disclosure provides power source assemblies aboard a watercraft. The power source assemblies can include: an engine having a crankshaft; a variable ratio drive assembly operably engaged with the crankshaft; and an engine powered accessory operably engaged with the variable ratio drive assembly. The present disclosure also provides methods for distributing power aboard a watercraft from a crankshaft of an engine. The methods can include: using a crankshaft of an engine to drive a variable ratio drive assembly; and using the variable ratio drive assembly to drive an engine accessory over a narrower RPM range while operating the crankshaft over a wider RPM range.

The present invention provides a novel floating and renewable energy-powered desalination vessel, which also functions as a wind turbine generator and wave energy generator platform. With energy derived from the wind and waves, the vessel performs reverse osmosis within a vertically positioned cylindrical section extending below a buoyancy chamber. The cylindrical section contains reverse osmosis membranes located above a seawater screening and filtration system, which serve as ballast. The entire vessel and power systems are configured to have the center of mass below the center of buoyancy, forming a vertically stable floating structure with minimum pitch, roll, and wave heave in high sea states. The electric power generated is utilized internally to produce desalinated water or hydrogen from the desalinated water's electrolysis, power an onboard data center, or power delivery to a shoreside power grid. In addition to a wind turbine generator and a wave energy generator, a photovoltaic array or a marine current generator may be utilized to power these applications. Alternatively, the desalination vessel operates with the assistance of shore-based power provided by cable.

The present invention provides a novel floating and renewable energy-powered desalination vessel, which also functions as a wind turbine generator and wave energy generator platform. With energy derived from the wind and waves, the vessel performs reverse osmosis within a vertically positioned cylindrical section extending below a buoyancy chamber. The cylindrical section contains reverse osmosis membranes located above a seawater screening and filtration system, which serve as ballast. The entire vessel and power systems are configured to have the center of mass below the center of buoyancy, forming a vertically stable floating structure with minimum pitch, roll, and wave heave in high sea states. The electric power generated is utilized internally to produce desalinated water or hydrogen from the desalinated water's electrolysis, power an onboard data center, or power delivery to a shoreside power grid. In addition to a wind turbine generator and a wave energy generator, a photovoltaic array or a marine current generator may be utilized to power these applications. Alternatively, the desalination vessel operates with the assistance of shore-based power provided by cable.

Various embodiments relate to a method and a harbour plant for mooring a floating body. The harbour plant includes a piled base structure provided with two upwards through sea level projecting sidewalls terminated above sea level and a laterally arranged bottom structure interconnecting the sidewalls, where a top surface of the bottom structure is arranged at a depth allowing the floating body to be floated in between the sidewalls, and where the floating body is arranged to be rigidly, but releasably supported by at least parts of the sidewalls. The method includes bringing the floating body into a position between the sidewalls and fixing rigidly the floating body to the vertical sidewalls of the base structure and still exposing the floating body more or less fully to buoyancy by allowing a water-filled gap at least between bottom of the floating body and a corresponding upper surface of the base structure.