A laser-powered ice-penetrating communications payload delivery vehicle for sub-ice submarine missions enables under-ice operations to exchange information with terrestrial facilities or satellite networks with communications methods otherwise blocked by an ice cap. The vehicle comprises an electronics bay, a payload bay, optics bay, and a melt optic with laser. The system and method of establishing communication where the vehicle, tethered to a sub-ice vessel, is released. The vehicle ascends to the bottom of an ice sheet and uses a laser to melt the ice, forming a borehole through which the vehicle continues to ascend. When buoyancy no longer advances the vehicle beyond sea level, the vehicle continues to melt a conical opening through the ice until unobstructed atmosphere is reached and bi-directional communication is established. Where the melting capacity cannot reach ice to continue melting, the vehicle mechanically advances itself toward the surface to establish high bandwidth, bi-directional communication.

A laser-powered ice-penetrating communications payload delivery vehicle for sub-ice submarine missions enables under-ice operations to exchange information with terrestrial facilities or satellite networks with communications methods otherwise blocked by an ice cap. The vehicle comprises an electronics bay, a payload bay, optics bay, and a melt optic with laser. The system and method of establishing communication where the vehicle, tethered to a sub-ice vessel, is released. The vehicle ascends to the bottom of an ice sheet and uses a laser to melt the ice, forming a borehole through which the vehicle continues to ascend. When buoyancy no longer advances the vehicle beyond sea level, the vehicle continues to melt a conical opening through the ice until unobstructed atmosphere is reached and bi-directional communication is established. Where the melting capacity cannot reach ice to continue melting, the vehicle mechanically advances itself toward the surface to establish high bandwidth, bi-directional communication.

This disclosure describes monitoring and operating subsea well systems, such as to perform operations in the construction and control of targets in a subsea environment. A submerisble ROV that performs operations in the construction and control of targets (e.g., well completion components) in a subsea environment, the ROV has one or more imaging devices that capture data that is processed to provide information that assists in the control and operations of the ROV and/or well completion system while the ROV is subsea.

This disclosure describes monitoring and operating subsea well systems, such as to perform operations in the construction and control of targets in a subsea environment. A submerisble ROV that performs operations in the construction and control of targets (e.g., well completion components) in a subsea environment, the ROV has one or more imaging devices that capture data that is processed to provide information that assists in the control and operations of the ROV and/or well completion system while the ROV is subsea.

A waterway sensor includes a housing having a sidewall with a plurality of openings, and at least one sensor element disposed within the housing. The at least one sensor element senses one or more properties of a waterway. A flexible elongate support is connected between the housing and a bank of the waterway. At least one of the housing and the elongate support is designed to bias the housing toward a desired position within the waterway.

A waterway sensor includes a housing having a sidewall with a plurality of openings, and at least one sensor element disposed within the housing. The at least one sensor element senses one or more properties of a waterway. A flexible elongate support is connected between the housing and a bank of the waterway. At least one of the housing and the elongate support is designed to bias the housing toward a desired position within the waterway.

An underwater camera system includes a camera assembly configured to scan a seabed while submerged under water and moving in a direction of travel. A buoyant support is coupled to the camera assembly and configured to position the camera assembly under water during the moving in the direction of travel. A stabilization assembly is coupled to the camera assembly and configured for adjusting an orientation of the camera assembly relative to the direction of travel.

An underwater camera system includes a camera assembly configured to scan a seabed while submerged under water and moving in a direction of travel. A buoyant support is coupled to the camera assembly and configured to position the camera assembly under water during the moving in the direction of travel. A stabilization assembly is coupled to the camera assembly and configured for adjusting an orientation of the camera assembly relative to the direction of travel.

The present invention relates to a remotely operated underwater robot device for removing marine biofouling, mainly aimed at organisms such as sun coral, settled on hulls of floating units for transporting oil and derivatives thereof, or on exploration and production platforms. The system comprises a remotely operated robot that removes the marine biofouling from said hulls, without damaging the hull, containing and capturing the waste. It is an intelligent device that is capable of operating in two modes: as an ROV to allow it to travel through the water, and as a crawler to perform the actual functions of removing the macrofouling containing sun coral and the functions resulting therefrom. It has non-georeferenced reference systems using acoustic elements to facilitate location by the operator. It uses computer vision to enter the parking areas without human assistance. It contains thrusters for controlling aquatic movements and self-levelling systems with control of the centre-of-buoyancy dynamics, and has wheels for movement, which can be electromagnets or a set of wheels that works in conjunction with a magnetic fastening system, both with variation in the coupling force. It has either a system for removing, containing, capturing and crushing the biofouling or a removal system using cavitation and mechanical impact that can have an approximate height of 30 centimetres, normally applied to sun coral.

The present invention relates to a remotely operated underwater robot device for removing marine biofouling, mainly aimed at organisms such as sun coral, settled on hulls of floating units for transporting oil and derivatives thereof, or on exploration and production platforms. The system comprises a remotely operated robot that removes the marine biofouling from said hulls, without damaging the hull, containing and capturing the waste. It is an intelligent device that is capable of operating in two modes: as an ROV to allow it to travel through the water, and as a crawler to perform the actual functions of removing the macrofouling containing sun coral and the functions resulting therefrom. It has non-georeferenced reference systems using acoustic elements to facilitate location by the operator. It uses computer vision to enter the parking areas without human assistance. It contains thrusters for controlling aquatic movements and self-levelling systems with control of the centre-of-buoyancy dynamics, and has wheels for movement, which can be electromagnets or a set of wheels that works in conjunction with a magnetic fastening system, both with variation in the coupling force. It has either a system for removing, containing, capturing and crushing the biofouling or a removal system using cavitation and mechanical impact that can have an approximate height of 30 centimetres, normally applied to sun coral.