Wakeboat ballast pump systems and methods are provided to monitor the operational condition and parameters of wakeboat ballast components. Systems and methods for sensing and measurement are provided to detect parameters associated with wakeboat ballast pumps and compartments, including systems and methods that can economically retrofit into existing wakeboat ballast systems. Systems and methods are also provided to enable automated action based on various operational conditions and parameters to improve the safety, automation, performance, convenience, and marketing advantage of wakeboat ballast pumps.

Embodiments include a retrofit pontoon system including a pontoon, the pontoon having a pontoon body defining a first cavity, the pontoon body having a first aperture; a retrofit assembly, the retrofit assembly including a selectively fillable container sized to pass through the first aperture; and a pump. The pump is operably coupled with the selectively fillable container such that operation of the pump selectively fills and drains water from the selectively fillable container, wherein 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 ballast water-free ship using a difference in the depth of the bottom shell plate between the bow/stern and the midship section and a construction method thereof. A stepped portion is formed between either the bow or the stern and the midship section, such that the depth of the bottom shell plate of either the bow or the stern differs from the depth of the bottom shell plate of the cargo containment in the midship section, so that cargo can be loaded and unloaded without ballast water operation.

A ballast water-free ship using a difference in the depth of the bottom shell plate between the bow/stern and the midship section and a construction method thereof. A stepped portion is formed between either the bow or the stern and the midship section, such that the depth of the bottom shell plate of either the bow or the stern differs from the depth of the bottom shell plate of the cargo containment in the midship section, so that cargo can be loaded and unloaded without ballast water operation.

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 motion absorbing system and method for a structure includes the coupling of a container to a structure. The container has a liquid disposed therein wherein a ullage is defined above a surface of the liquid. An elastic element is positioned in the liquid. The elastic element has a natural frequency tuned to damp motion of the liquid.

A motion absorbing system and method for a structure includes the coupling of a container to a structure. The container has a liquid disposed therein wherein a ullage is defined above a surface of the liquid. An elastic element is positioned in the liquid. The elastic element has a natural frequency tuned to damp motion of the liquid.

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.