A marine wind power generation floating body according to an embodiment of the present disclosure can be coupled to a tower used for wind power generation and is provided at sea. The marine wind power generation floating body includes a floating main body which is formed at a predetermined length and which has a circular transverse cross section, a ballast part positioned on one side of the floating main body, a damping plate positioned at one end of the floating main body, and formed with a diameter that is larger than the outer diameter of one side of the floating main body, and a pitching/rolling damping part which is positioned on the other side of the floating main body, and which damps the horizontal pitching and rolling of the floating main body.

An exemplary autonomous seabased resupply system includes an unmanned blob positioned in a water body, the blob containing fuel, a pump on the blob configured to pump the fuel through a conduit to a craft, and a ballast system operable to change a vertical position of the blob in the water body.

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 bade 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.

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 bade 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.

An apparatus and method of measuring, monitoring, recording and verifying the uptake and discharge of ballast water on marine vessels to ensure that they comply with the ballast water discharge standards set by international bodies, the apparatus includes an arrangement of small sampling pipes, valves, sampling pump, flow meter, Ballast Water Monitor, Ballast Water Sensors Module and Controller. The method comprises measuring the concentration of the bacteria and pathogens in the sampled ballast water during ballasting and de-ballasting by the Ballast Water Monitor and compared against the regulatory standards and historical data of similar ship data and ballast water data. The method also identifies and isolates specific ballast water tank that holds non-compliant ballast water so that when compliant water is available, the non-complaint ballast water shall be flushed out from the identified specific ballast water tank with the compliant water. All information are saved in a secure, tamper-proof and encrypted format so that they are verifiable and traceable to ensure that no non-compliance ballast water has been discharged overboard at ports at all times.

An apparatus and method of measuring, monitoring, recording and verifying the uptake and discharge of ballast water on marine vessels to ensure that they comply with the ballast water discharge standards set by international bodies, the apparatus includes an arrangement of small sampling pipes, valves, sampling pump, flow meter, Ballast Water Monitor, Ballast Water Sensors Module and Controller. The method comprises measuring the concentration of the bacteria and pathogens in the sampled ballast water during ballasting and de-ballasting by the Ballast Water Monitor and compared against the regulatory standards and historical data of similar ship data and ballast water data. The method also identifies and isolates specific ballast water tank that holds non-compliant ballast water so that when compliant water is available, the non-complaint ballast water shall be flushed out from the identified specific ballast water tank with the compliant water. All information are saved in a secure, tamper-proof and encrypted format so that they are verifiable and traceable to ensure that no non-compliance ballast water has been discharged overboard at ports at all times.

An unmanned vehicle including a vehicle body, propulsion system, maneuvering system, vehicle control system, rack, sensor, and a power supply. The vehicle control may be used to control the unmanned vehicle in combination with the propulsion and the maneuvering system. The rack may include a retractable mount that may move between a down position and an up position. The sensor system may include a plurality of transient object detection sensors. The plurality of transient object detection sensors may include a sensor adapted to detect an item of interest and may provide an item of interest signal to the vehicle control system. The vehicle control system may identify an item of interest classification and may provide a classification signal. The classification signal may be determined by the item of interest classification and may be utilized to avoid detection of the unmanned vehicle by the item of interest.

Wakeboats that include an aquatic invasive species control apparatus are provided. These wakeboats can include: a wakeboat with a hull; at least one throughhull fitting in the hull of the wakeboat; an irradiation chamber in fluid communication with the at least one throughhull fitting, the irradiation chamber having a radiation source; and at least one water destination aboard the wakeboat. Methods for irradiating invasive aquatic species aboard a wakeboat are also provided. The methods can include: receiving water from outside the wakeboat hull; and irradiating water aboard the wakeboat prior to discharging the water.

A buoyant module comprising a base configured for being buoyantly supported within a body of water, wherein said base defines a space which is in fluid communication with said body of water; a fluid-holding container sized and fitted for being received within said space and for moving in a vertical dimension relative to said base; and wherein a vertical position of said container relative to said base is determined, at least in part, by a fluid level in said container.

A buoyant module comprising a base configured for being buoyantly supported within a body of water, wherein said base defines a space which is in fluid communication with said body of water; a fluid-holding container sized and fitted for being received within said space and for moving in a vertical dimension relative to said base; and wherein a vertical position of said container relative to said base is determined, at least in part, by a fluid level in said container.