Thermal warming suits for a human occupant of a wet submersible vehicle are described. The thermal warming suits provide a dedicated envelope configured to encase at least a portion of the human occupant in a deformable suit that can be assembled around or donned, as well as be removed, by the occupant or others before or after entry and seating in or on the wet submersible vehicle, while underwater or surfaced. The suits provide a deformable, weight and space (i.e. volume) conscious, collapsible loose fitting perimeter around the occupant. The suits can be used to create a pneumatic barrier around at least a portion of the occupant by using a gas such as air provided from a gas reservoir to force water from the interior of the suit.

Thermal warming suits for a human occupant of a wet submersible vehicle are described. The thermal warming suits provide a dedicated envelope configured to encase at least a portion of the human occupant in a deformable suit that can be assembled around or donned, as well as be removed, by the occupant or others before or after entry and seating in or on the wet submersible vehicle, while underwater or surfaced. The suits provide a deformable, weight and space (i.e. volume) conscious, collapsible loose fitting perimeter around the occupant. The suits can be used to create a pneumatic barrier around at least a portion of the occupant by using a gas such as air provided from a gas reservoir to force water from the interior of the suit.

An underwater data center includes an electronic device; a housing member that houses the electronic device and that is configured to be disposed under water; and a heat exchanger that is provided at the housing member and that is configured to discharge, into the water, heat discharged from the electronic device, with a face of the heat exchanger that discharges the heat making contact with the water, an opening being formed in a bottom face of the housing member and placing an inside of the housing member in communication with the water.

A system for use by a diver during an underwater dive. An autonomous underwater vehicle (one component of the system, AUV) comprises a component for detecting that the AUV has entered water, an AUV acoustic transceiver, a plurality of AUV sensors, a propulsion unit, a processor for determining dive information and diver information responsive to data from one or both of the AUV acoustic transceiver and the plurality of AUV sensors, and one or more cameras. Diver equipment carried by the diver comprises a plurality of diver sensors and a diver acoustic transceiver for receiving sensed information from the plurality of diver sensors and communicating the sensed information to the AUV, and for receiving information from the AUV acoustic transceiver.

A watercraft with a hull has a flow channel, or is associated with a flow channel, a motor-driven water-acceleration arrangement is associated with the flow channel and the motor is connected to an energy accumulator. In order to improve user convenience, two energy accumulators are integrated into the hull. The energy accumulators are arranged on both sides of the center longitudinal plane running in the longitudinal direction of the hull.

A watercraft with a hull has a flow channel, or is associated with a flow channel, a motor-driven water-acceleration arrangement is associated with the flow channel and the motor is connected to an energy accumulator. In order to improve user convenience, two energy accumulators are integrated into the hull. The energy accumulators are arranged on both sides of the center longitudinal plane running in the longitudinal direction of the hull.

An arrangement comprises: a plurality of diver propulsion vehicles (1), each configured for propelling at least one diver, wherein each diver propulsion vehicle (1) comprises a wireless communication interface (9, 10, 13) configured for providing a wireless communication, a support (30) for mechanically coupling the plurality of diver propulsion vehicles (1), wherein the support (30) is configured for mechanically coupling the plurality of diver propulsion vehicles (1) side-by-side or longitudinally via the support (30).

An arrangement comprises: a plurality of diver propulsion vehicles (1), each configured for propelling at least one diver, wherein each diver propulsion vehicle (1) comprises a wireless communication interface (9, 10, 13) configured for providing a wireless communication, a support (30) for mechanically coupling the plurality of diver propulsion vehicles (1), wherein the support (30) is configured for mechanically coupling the plurality of diver propulsion vehicles (1) side-by-side or longitudinally via the support (30).

A method and device for displaying computer content associated with a propulsion system, include: a standalone computer element (MO), the computer element including a display screen (4) in particular for displaying the computer content; a standalone propulsion element (PO) for moving an operator; an element for securing the computer element to the propulsion element; and an element for modifying the display of the computer content according to the movement of the operator, given that the movement of the operator takes place in a sub-aquatic environment.