Systems, methods, and apparatuses are described herein for providing electrical power to a marine vehicle. In some aspects, a marine vehicle includes a power system arranged to receive and store electrical power delivered from a solar panel assembly. The power system may include one or more batteries. The vehicle also includes a processor arranged to determine an extension time and an retraction time for a solar panel assembly and a controller that, in response to instructions from the processor, is arranged to extend the solar panel assembly and retract the solar panel assembly. The solar panel assembly is arranged to be configured in at least one of an extended position and a retracted position. The solar panel assembly includes one or more solar panels where the solar panel assembly is in electrical communication with the power system.

A solar powered electric ship system comprises an electric ship, multiple inflatable barges, and multiple inflatable non-imaging non-tracking solar concentrator based concentrating photovoltaic systems. The entire system is configured with the multiple inflatable non-imaging non-tracking solar concentrator based concentrating photovoltaic systems mounted on the inflatable barges, and with the inflatable barges mechanically and electrically connected to the electric ship. When in operation, the electric ship dragged the barges to navigate together with it, and have the inflatable non-imaging non-tracking solar concentrator based photovoltaic system to power it. The configuration dramatically reduce the battery bank size of the electric ship and make the portable floating concentrating photovoltaic system ultra-high efficiency, extremely low cost, and super light.

A method, system, and apparatus for collecting waste. In one embodiment, an autonomous plastic collecting robot (APCR) device for collecting waste may include a net structure that picks up micro plastic particles dispersed in water; a tube that transports the micro plastics collected by the net structure into a main internal container; an artificial tongue for collecting larger plastics, the artificial tongue comprised of a rolling staircase with fork-like structures in placed of the stairs; a plastic degrading medium contained in the main internal container; a no-joint tail structure which acts as the primary power source for the APCR, the no-joint tail structure housing dielectric elastomer materials and a rotation shaft located between at least two electric generators.

A solar boat with an adjustable angle of a solar panel of the present disclosure comprises: a cabin unit; a boat body provided below the cabin unit and including a first fixing unit and a second fixing unit; a solar panel unit provided above the cabin unit and configured to convert solar energy into electrical energy; a first pole provided with a first connector at an upper end thereof and connected to a front left bottom of the solar panel unit via the first connector, and provided with a second connector at a lower end thereof and connected to the boat body via the second connector; a second pole provided with a third connector at an upper end thereof and connected to a front right bottom of the solar panel unit via the third connector, and provided with a fourth connector at a lower portion thereof and connected to the boat body via the fourth connector; a third pole provided with a fifth connector at an upper end thereof and connected to a rear left bottom of the solar panel unit via the fifth connector, provided with a sixth connector at a lower portion thereof and connected to the boat body via the sixth connector, and provided with a seventh connector below the sixth connector and connected to an upper end of a first adjustment unit via the seventh connector; a fourth pole provided with an eighth connector at an upper end thereof and connected to a rear right bottom of the solar panel unit via the eighth connector, provided with a ninth connector at a lower portion thereof and connected to the boat body via the ninth connector, and provided with a tenth connector below the ninth connector and connected to an upper end of a second adjustment unit via the tenth connector; the first adjustment unit connected to the seventh connector at an upper end thereof, provided with an eleventh connector at a lower end thereof and connected to the first fixing unit via the eleventh connector, and being adjustable in its length; and the second adjustment unit connected to the tenth connector at an upper end thereof, provided with a twelfth connector at a lower end thereof and connected to the second fixing unit via the twelfth connector, and being adjustable in its length, and has the effects that can perform efficient solar power generation according to the surrounding environment or the direction of sunlight by enabling the angle adjustment of the solar panels installed on the roof of the solar boat, and that can reduce the volume of the solar boat when anchored, and can resolve the problem of taking up a lot of space by the fixed solar panels when anchored by enabling the angle adjustment of the solar panels installed on the roof of the solar boat and the storag

A propulsion system for a boat comprises a plurality of aerofoils connected to a main mast. At least one of the aerofoils is a displaceable aerofoil adapted to be displaced along the main mast between an open position and a closed position. When the displaceable aerofoil is in its open position the aerofoils together form a sail of open sail area. When the displaceable aerofoil is in its closed position at least some of the aerofoils overlap to form a sail of closed sail area, the closed sail area being less than the open sail area. The propulsion system can include a displacement mechanism to displace the displaceable aerofoil between its open and closed positions; at least one of the aerofoils having a solar panel thereon; and/or a stub mast extending along and free to rotate about a stub axis and connected to the main mast by a stub pivot.

The invention relates to a water-going assembly comprising a first buoyant structure (S1) comprising at least two hulls (F1, F1′; F11, F11′, F12, F12′) delimiting between them a space (E1) and a photovoltaic arrangement (PH1) occupying a substantial proportion of the footprint of the buoyant structure, and a second buoyant structure (S2) provided with an electric thruster (P2) and with a battery (B2), means for assembling the two buoyant structures detachably, with means of electrical connection between the photovoltaic arrangement of the first buoyant structure and the battery of the second buoyant structure, the latter being able to be used for moving the two structures (S1, S2) with a directional guidance, or as an autonomous motorized marine craft.

A marine vessel can be propelled by using wind or solar energy. This propulsion results in the forward movement and six degrees of motion (roll, heave, pitch, yaw, surge, and sway) of the marine vessel. This invention capitalizes on the fact that solar, wind and wave energy are cyclical by nature. The present invention enables the vessel to manage stored and harvested energy from these energy sources and use the stored energy during periods when the external natural sources of energy are not available in adequate quantities to maintain a reasonable speed of advance for the marine vessel. The vessel's natural energy management system (NEMS) manages it in such a way that harvesting of the energy during high energy cycles, storing it and using it when needed during low external energy cycles, allows a marine vessel to maintain faster average speed without reliance on any fossil or chemical fuel and by only using renewable energy sources.

A system for providing solar power to a watercraft includes a hull having an outer surface, defining a recess extending inward and offset from the outer surface by a distance, and configured to float on water. The system further includes a solar panel configured to fit within the recess and having a thickness that is substantially equal to the distance such that an outer edge of the solar panel is substantially aligned with the outer surface of the hull.

A system for providing solar power to a watercraft includes a hull having an outer surface, defining a recess extending inward and offset from the outer surface by a distance, and configured to float on water. The system further includes a solar panel configured to fit within the recess and having a thickness that is substantially equal to the distance such that an outer edge of the solar panel is substantially aligned with the outer surface of the hull.

Aquatic environment monitoring devices, systems and methods are provided. An aquatic vehicle includes a body supporting a drive sub-system configured to drive the aquatic vehicle along a travel path, at least one sensor configured to obtain a plurality of sensor data points at a plurality of different locations along the travel path, a GPS module configured to track movement of the aquatic vehicle along the travel path, and a microcontroller configured to compile the sensor data points with GPS location data corresponding to a location where each of the sensor data points was obtained. A remote computer is configured to receive the compiled data from the microcontroller and, based thereon, provide an output correlating the sensor data points with the GPS location data.