Embodiments include a retrofit pontoon system including a pontoon, the pontoon having a pontoon body defining a first cavity, a retrofit assembly, the retrofit assembly including a tube, wherein the tube is sized to pass through a first aperture formed in the pontoon body and a selectively fillable container, where the tube is operably coupled with the selectively fillable container, and a pump, the pump being coupled with the tube such that operation of the pump selectively fills and drains water from the selectively fillable container, where filling the selectively fillable container lowers the profile of the pontoon in the water and emptying the selectively fillable container raises the profile of the pontoon in the water.

Embodiments include a retrofit pontoon system including a pontoon, the pontoon having a pontoon body defining a first cavity, a retrofit assembly, the retrofit assembly including a tube, wherein the tube is sized to pass through a first aperture formed in the pontoon body and a selectively fillable container, where the tube is operably coupled with the selectively fillable container, and a pump, the pump being coupled with the tube such that operation of the pump selectively fills and drains water from the selectively fillable container, where filling the selectively fillable container lowers the profile of the pontoon in the water and emptying the selectively fillable container raises the profile of the pontoon in the water.

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 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.

Wakeboat ballast compartment fluid level sensing assemblies are provided that can include: a wakeboat having a hull; a ballast compartment associated with the hull; a nonconductive sensor chamber in fluidic communication with the ballast compartment; and at least one conductive electrode associated with the sensor chamber. Methods for sensing a fluid level within a ballast compartment aboard a wakeboat are also provided. The methods can include maintaining fluid communication between the ballast compartment and a sensor chamber; and determining the electrical communication of electrodes operatively associated with the sensor chamber.

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.

A method for controlling an inclination of a floating wind turbine platform Position data associated with an orientation of the floating wind turbine is received. A heel angle in reference to the floating wind turbine platform is determined based on the position data. A first signal for adjusting at least one of a blade pitch of a set of turbine blades and a torque of a generator is sent based on the determined heel angle. A second signal for distributing ballast among at least three stabilizing columns is also sent. The second signal for distributing the ballast is based on the determined heel angle and the first signal. The first and second signals may be adjusted to account for startup and shutdown procedures and for future changes to wind speed and velocity.

A method for controlling an inclination of a floating wind turbine platform Position data associated with an orientation of the floating wind turbine is received. A heel angle in reference to the floating wind turbine platform is determined based on the position data. A first signal for adjusting at least one of a blade pitch of a set of turbine blades and a torque of a generator is sent based on the determined heel angle. A second signal for distributing ballast among at least three stabilizing columns is also sent. The second signal for distributing the ballast is based on the determined heel angle and the first signal. The first and second signals may be adjusted to account for startup and shutdown procedures and for future changes to wind speed and velocity.

A reverse osmosis water production apparatus for use in a body of water includes a first section defining a buoyancy chamber and an elongate second section connected to the first section and configured to define an elongate chamber which extends downward beneath a waterline in use. The elongate chamber is provided with a plurality of elongate reverse osmosis membrane tubes, each tube containing a reverse osmosis membrane. A longitudinal axis of each reverse osmosis membrane tube is substantially parallel with a longitudinal axis of the elongate chamber and the reverse osmosis membrane tubes are arranged around a passage.

According to one or more embodiments disclosed herein is a method of transporting equipment between sea-surface and seafloor by providing a structure with a subsea equipment package mounted thereon. The structure is used for installation and recovery in a subsea environment by changing the buoyancy of the structure or ballasting the structure to effect a controlled sinking motion.