The present invention discloses a device and system for magnetographic analysis of mechanical flaws and defects along structures located underwater for example, metallic pipelines, utilizing an autonomous magnetic tomography method (MTM) apparatus based on the inverse magnetostrictive effect for magnetographic identification, in the form of an array of flexible autonomous undersea vehicle (AUV) torpedo constructions of interconnected elements or pods. The array of AUV torpedo constructions are flexibly linked together so that the device can readily navigate within the contours of pipeline to be inspected using the flow media as propulsion means or alternatively by means of independent motive means without interfering with the system flow. The torpedo construction elements or pods each contain three MTM sensors situated 120 degrees apart on a non-perpendicular cross section arrangement, and perform a variety of independent functions. e.g., data storage data, sensor data memory unit, odometer distance measurements, GPS location, geomagnetic navigation capability.

A submarine vehicle may include a storage area for storing loads. The submarine vehicle may further include a pressure hull. The submarine vehicle is configured to pick loads up from a seabed and/or set loads down on the seabed. The storage area may be positioned outside the pressure hull and, in some examples, between numerous pressure hulls. Further, the storage area may include a lower hatch disposed on an underside of the pressure hull or an upper hatch disposed on a top side of the pressure hull. Some submarine vehicles may include a load transporting system for picking the load up from the seabed, setting the load down on the seabed, and/or conveying the load within the storage area.

An autonomous underwater vehicle (AUV) for guiding other AUVs during a marine seismic survey. The guiding AUV includes a housing; a propulsion system located inside the housing; and an acoustic positioning system attached to an outside the housing. The acoustic positioning system emits at least three chirps from three different locations.

An underwater powered observation system useful for ice fishing and capable of driving down an augured hole in the ice in a particular orientation that receives propulsion directions via a miniature multi-conductor cable connected to a color monitor integral to a control unit. The submersible vehicle assembly is powered by an onboard rechargeable battery that energizes both horizontal and vertical thrusters to guide and move the vehicle assembly through the water from directions communicated by the control unit. The submersible vehicle assembly may include a laser adapted to be directed to the underside of ice so as to locate the vehicle assembly allowing the user to cut a hole using a standard commercial ice auger in the ice at or near fish. In this manner the vehicle assembly may be utilized for the underwater tasks of locating fish, observing scenery, boat and pier inspection, object recovery, and other underwater tasks. The submersible vehicle assembly is particularly useful for ice fishing where such submersible vehicle assembly may controlled under the ice to locations of fish.

An underwater LED light for use in high ambient pressure environments having a housing, a transparent pressure-bearing window, an MCPCB having one or more LEDs, and a multilayer stack of spacers for carrying loads applied to the window to the MCPCB and to the housing.

The invention relates to a launch apparatus for an Unmanned Underwater Vehicle—in particular, for an Autonomous Underwater Vehicle or for a Remotely Operated Vehicle—with a launching tube having an inner wall and an outlet, and the Unmanned Underwater Vehicle contained within the launching tube, whereby the Unmanned Underwater Vehicle has a vehicle casing with a vehicle casing inhomogeneity, such that an ejection of the Unmanned Underwater Vehicle causes different contact loads between the vehicle casing and the inner wall, whereby the Unmanned Underwater Vehicle has a detachable compensating form, which is designed in such a way that the vehicle inhomogeneity is compensated, such that the result is a combination of the Unmanned Underwater Vehicle and the detachable compensating form, the combination whereof, when ejected, causes a substantially more uniform contact load to occur between the combination and the inner wall.

A hairtail-imitating high-speed soft robot driven based on chemical exergonic reaction, including a fish head module, a fish body module and a fishtail module; wherein the fish head module includes a fish head shell, the fish head shell is internally provided with a rigid exergonic reaction bin, a combustible agent storage unit, a combustion promoter storage unit, and an exergonic reaction excitation device, and a rigid push plate is in sliding fit in the rigid exergonic reaction bin; the fish body module includes a flexible fishbone, restraint assemblies, and flexible fish skin; and the fishtail module includes a fishtail fixing block.

The present invention relates to a marine structure comprising a launch and recovery system for a submersible vehicle, and methods of operating the marine structure. The system comprises: a docking receiver, a towing head comprising a locking mechanism and being connectable to the docking receiver (13), a towing arrangement adapted to mechanically connect the towing head to the marine structure and being adapted to control the distance between the towing head and the docking receiver, and a lifting device connected to the docking receiver and being adapted to move the docking receiver relative to the marine structure. The lifting device can arrange the docking receiver in a towing head receiving and/or releasing position in which the docking receiver: (i) is completely submerged into the body of water, and (ii) is prevented from moving relative to the marine structure.

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 seabased resupply system includes a fuel containment structure containing fuel and extending fore and aft along a longitudinal axis, a pump on the fuel containment structure operable to pump the fuel, containers located on an exterior of opposite lateral sides of the fuel containment structure, and an operating system located inside one or more of the containers, the operating system comprising at least one selected from a power supply, a communication system, and a control processor.