Provided is a propeller for a submersible, comprising a housing (1) having a cylindrical structure with two open ends, a stator sleeve (2) having a cylindrical structure with one open end, the stator sleeve suspended in an internal cavity of the housing (1), a motor stator (3) fixed inside the stator sleeve (2), a rotor sleeve (4) having a cylindrical structure with one open end and disposed on the stator sleeve (2), a motor rotor (5) fixed to an inner wall of the rotor sleeve (4), and a propeller (6) fixed to an outer wall of the rotor sleeve (4). The propeller (6) of the underwater propeller is directly fixed to the rotor sleeve (4) so that the structure of the motor is compact, and the rotational shaft transmission is not required so that the length of the propeller is shortened and the volume is reduced.

A cooling apparatus for an underwater platform comprising: an evaporator block fabricated from a thermally conductive material and having a first surface that is shaped so as to releasably mate to an exterior surface contour of the underwater platform; a heat pipe having a working fluid sealed therein, wherein the heat pipe has a first end and a second end, and wherein the first end is in thermal communication with the evaporator block; a condenser block in thermal communication with the second end of the heat pipe; and a plurality of spring clamps mounted to the evaporator block and configured to bias the first surface of the evaporator block against the exterior surface of the underwater platform such that heat from the exterior surface of the underwater platform is transferred to the ambient water via the evaporator block, heat pipe, and condenser block.

A robotic fish comprises one or more torque reaction engines and a fish body, wherein the torque reaction engine cyclically oscillates and causes a wave to propagate across the fish body, including through a flexible wing, accelerating thrust fluid and propelling the robotic fish.

A system and method for safely, efficiently and reliably deploying a payload, such as a remotely operated vehicle (ROV) beneath the surface of the water. The ROV is configured to capture data and/or information and to transmit the data and/or information to a base station. The system comprises an unmanned aerial system (UAS) having a frame comprising a support structure configured to receive the payload, wherein the payload may be deployed beneath the surface of water and a winch is configured to deploy the ROV from and retrieve the ROV back to the UAS using a tether. The tether is configured to wirelessly transmit telemetry, data, and/or information between the UAS and the ROV in real time.

A vehicle for aerial-aquatic locomotion is provided. The vehicle may include a propeller, an electric motor operably coupled to the propeller and configured to rotate the propeller, a maneuvering assembly configured to change an attitude and altitude of the vehicle, and a controller operably coupled to the electric motor and the maneuvering assembly. The controller may be configured to receive a command for the vehicle to exit a first medium and enter a second medium, compute or retrieve a hybrid trajectory, and control the electric motor and the maneuvering assembly to maneuver the vehicle in accordance with the hybrid trajectory.

A marine vessel comprising: at least one buoyant tubular foil; and at least one baffle plate positioned about the perimeter of the at least one buoyant tubular foil so as to protrude into the flow of water passing by the perimeter of the at least one buoyant tubular foil, whereby to create a high-pressure zone fore of the at least one baffle plate and a low-pressure zone immediately aft of the at least one baffle plate, whereby to create a dense stream of supercavitated water immediately aft of the at least one baffle plate.

An in-water refueling system for unmanned undersea vehicles with fuel cell propulsion. The in-water refueling system may store a liquid such as water at constant pressure and may dispense gases such as hydrogen or oxygen for refueling. In its basic configuration, the in-water refueling system may comprise a tank with an interior space for storing the liquid; a pump for regulating the flow of liquid into the interior space of the tank; an electrolysis stack assembly for converting the liquid into one or more gases; and open-bottom cylinders for storing and dispensing the gases. Each open-bottom cylinder may comprise a float sensor for determining the amount of fluids entering its cylindrical space. The in-water refueling system may further comprise a controller for regulating a temperature and a fluid pressure in the tank. Dispense lines and valves may be utilized to release the gases from the tank.

Image recording as long as possible during one activity is required in deep sea exploration. Necessity of multi-directional image recording, optical and chemical observations and probing of mineral resources of seabed are also increased. There is no underwater exploration device enable these requirements. It is disclosed that at least one battery-driven underwater exploration body having three pressure-resistant hollow glass spheres for housing an image capturing device, an illumination device, a recording device, an acoustic communication device and a control device controlling thereof and at least one battery body having an approximately the same shape and structure as the underwater exploration body are connected with each other by a connecting tool to provide the connectedly-formed underwater exploration device.

Systems and methods are disclosed for autonomous joint detection-classification of acoustic sources of interest. Localization and tracking from unmanned marine vehicles are also described. Based on receiving acoustic signals originating above or below the surface, a processor can process the acoustic signals to determine the target of interest associated with the acoustic signal. The methods and systems autonomously and jointly detect and classify a target of interest. A target track can be generated corresponding to the locations of the detected target of interest. A classifier can be used representing spectral characteristics of a target of interest.

A catch handling system includes a catch collection system. The catch collection system includes one catch handling depot; one or more trawls; and a catch transport system, where the catch transport system includes a transport system, and where the transport system includes a transport node. The transport node includes a releasable connection to a catch handling fleet carrier drone and to one or more units of a catch handling fleet.