A self-deployable apparatus for facilitating collecting data from multiple depths of water bodies. Further, the self deployable apparatus comprises a main body, substances, a sensor, a storage device, and a power source. Further, the substances in amounts are to be disposed in a second interior space of the main body for sinking the self-deployable apparatus to a depth of water body. Further, the amounts of the substances undergo a thermochemical reaction at a temperature for producing a gaseous substance. Further, a check valve of the main body expels a portion of the gaseous substance from the second interior space for rising the self-deployable apparatus to a surface of the water body. Further, the sensor generates sensor data based on detecting a parameter of a water sample. Further, the storage device stores the sensor data. Further, the power source powers the sensor and the storage device.

A sensor platform is provided with a rigid hull having a planar shape having a bow, stern, a port and a starboard side. The platform includes an inflatable perimeter tube having sides extending along a perimeter of the hull. A tow connection is at the bow and rigid control surfaces are at the stern. A planar sensor array is disposed within the platform. The planar sensor array includes inflatable sensor panels attached to the port and a starboard side of the perimeter tube. Each of the inflatable sensor panels has a plurality of sensors embedded with electrical conductors for power and data transfer. A manifold disposed within the platform operationally connects to the inflatable perimeter tube and the inflatable sensor panels. An electrical controller disposed within the platform connects to the sensors and the manifold.

A sensor platform is provided with a rigid hull having a planar shape having a bow, stern, a port and a starboard side. The platform includes an inflatable perimeter tube having sides extending along a perimeter of the hull. A tow connection is at the bow and rigid control surfaces are at the stern. A planar sensor array is disposed within the platform. The planar sensor array includes inflatable sensor panels attached to the port and a starboard side of the perimeter tube. Each of the inflatable sensor panels has a plurality of sensors embedded with electrical conductors for power and data transfer. A manifold disposed within the platform operationally connects to the inflatable perimeter tube and the inflatable sensor panels. An electrical controller disposed within the platform connects to the sensors and the manifold.

A submergible wave energy converter and method for using the same are described. In one embodiment, the wave energy converter may be used for deep water operations. In one embodiment, the submergible wave energy converter is an autonomous unmanned vehicle that enables remote ocean power generation. In one embodiment, the wave energy converter apparatus comprises an absorber having a body with an upper surface and a bottom surface and at least one power take-off (PTO) unit coupled to the absorber and configured to displace movement of the absorber body relative to a reference, where the power take-off unit is operable to perform motion energy conversion based on displacement of the absorber body relative to the reference in response to wave excitation, and where the power take-off unit is operable to return the absorber body from a displaced position to a predefined equilibrium position and to provide a force acting on the absorber body for energy extraction.

A submergible wave energy converter and method for using the same are described. In one embodiment, the wave energy converter may be used for deep water operations. In one embodiment, the submergible wave energy converter is an autonomous unmanned vehicle that enables remote ocean power generation. In one embodiment, the wave energy converter apparatus comprises an absorber having a body with an upper surface and a bottom surface and at least one power take-off (PTO) unit coupled to the absorber and configured to displace movement of the absorber body relative to a reference, where the power take-off unit is operable to perform motion energy conversion based on displacement of the absorber body relative to the reference in response to wave excitation, and where the power take-off unit is operable to return the absorber body from a displaced position to a predefined equilibrium position and to provide a force acting on the absorber body for energy extraction.

An underwater data capture and transmission system has a base configured to sink in water, at least one sensor configured to capture data while submerged in water, a processing unit configured to receive data collected by the sensor, and a variable buoy. The variable buoy has a ballast system configured to adjust a depth of the variable buoy in the water, and a communication device configured to transmit data to a remote communications device. The system further has at least one tether connecting at least the base, the processing unit, and the variable buoy.

An underwater data capture and transmission system has a base configured to sink in water, at least one sensor configured to capture data while submerged in water, a processing unit configured to receive data collected by the sensor, and a variable buoy. The variable buoy has a ballast system configured to adjust a depth of the variable buoy in the water, and a communication device configured to transmit data to a remote communications device. The system further has at least one tether connecting at least the base, the processing unit, and the variable buoy.

Floats including a central chamber, a peripheral chamber, and a ballast matter. The peripheral chamber is radially spaced from the central chamber proximate a radial periphery of the float in a substantially common plane with the central chamber. The ballast matter is disposed in either the central chamber or the peripheral chamber. The float is buoyant and configured to float on an external liquid surface in a substantially horizontal plane. The ballast matter operates to maintain the center of gravity of the float proximate to the geometric center of the float when the float tilts relative to the horizontal plane.

Floats including a central chamber, a peripheral chamber, and a ballast matter. The peripheral chamber is radially spaced from the central chamber proximate a radial periphery of the float in a substantially common plane with the central chamber. The ballast matter is disposed in either the central chamber or the peripheral chamber. The float is buoyant and configured to float on an external liquid surface in a substantially horizontal plane. The ballast matter operates to maintain the center of gravity of the float proximate to the geometric center of the float when the float tilts relative to the horizontal plane.

A mooring buoy includes a first floating body, a second body slidingly connected to the first and normally submerged, a mooring line connected to the second body by a connector housed in a seat in the first body and movable between a retracted position and a protruding position, enabling fixing the mooring line. The buoy further includes at least one chamber, in one or both of the first and second bodies, a fluid circuit admitting fluid into and out of the chamber, and a control unit connected to the fluid circuit. The control unit controls the fluid circuit to vary the amount of the fluid in the chamber, causing a variation of the immersion depth of the first body with respect to the second body or vice versa and, consequently, movement of the connecting element between the retracted and protruding positions.