The invention relates to a system (2), having: a buoyant buoy (4), and a floating hose (6) which has a plurality of buoyant hose segments (8) which are coupled in series. The buoy (4) has a liquid outlet connection (12) which is connected to the floating hose (6), so that the floating hose (6) is arranged in a geometrical arrangement with respect to the buoy (4). A plurality of node units (18) are fastened in a distributed manner to the floating hose (6) and the buoy (4). Each node unit (18) is designed to establish, by means of an associated radio unit, a respective radio link (22, 24, 26, 28) to each of at least two of the further radio units of the respective node units (18, 42, 44, 46, 48), so that a radio network (30) is created. Each node unit (18) is designed to determine a relative distance (32, 34, 36, 38) from each further node unit (18) on the basis of the respective radio link.

The invention relates to a system (2), having: a buoyant buoy (4), and a floating hose (6) which has a plurality of buoyant hose segments (8) which are coupled in series. The buoy (4) has a liquid outlet connection (12) which is connected to the floating hose (6), so that the floating hose (6) is arranged in a geometrical arrangement with respect to the buoy (4). A plurality of node units (18) are fastened in a distributed manner to the floating hose (6) and the buoy (4). Each node unit (18) is designed to establish, by means of an associated radio unit, a respective radio link (22, 24, 26, 28) to each of at least two of the further radio units of the respective node units (18, 42, 44, 46, 48), so that a radio network (30) is created. Each node unit (18) is designed to determine a relative distance (32, 34, 36, 38) from each further node unit (18) on the basis of the respective radio link.

A liquefied natural gas (LNG) bunkering equipment test and evaluation system is provided. The system includes a storage tank module configured to store a liquefied natural gas, a supply module for connecting the storage tank module and the bunkering module, a bunkering module configured to perform bunkering by being supplied with the liquefied natural gas, a simulation module provided at a part under the bunkering module and the supply module and the simulation module is configured to simulate a maritime situation by giving a fluidity to the bunkering module and the supply module, and a controller configured to control a driving of the simulation module, thereby simulating various situations of sea areas by giving fluidity to the storage tank module and the bunkering module.

A system (1) for transfer of a fluid product comprising a transfer pipe for the fluid product having several sections, called first pipe (2), and having an end provided with a coupling system (5) configured for the connection of the first pipe (2) to a target duct, and further comprising a support structure (4) for the first pipe (2), comprising an inner branch (41) which is mounted on a base (42) and an outer branch (43). The first transfer pipe (2) comprises a flexible section of pipe (21) having a proximal end (210) suspended from the support structure (4) and a rigid section of pipe (22) connected to a distal end (211) of the flexible section of pipe (21) and provided at its free end with the coupling system (5), the transfer system comprising suspension means configured for rigidly suspending, at the location of a first end thereof, the rigid section of pipe (22) from the outer branch (43) via articulation means permitting rotation around a vertical axis and at least one horizontal axis.

A system (1) for transfer of a fluid product comprising a transfer pipe for the fluid product having several sections, called first pipe (2), and having an end provided with a coupling system (5) configured for the connection of the first pipe (2) to a target duct, and further comprising a support structure (4) for the first pipe (2), comprising an inner branch (41) which is mounted on a base (42) and an outer branch (43). The first transfer pipe (2) comprises a flexible section of pipe (21) having a proximal end (210) suspended from the support structure (4) and a rigid section of pipe (22) connected to a distal end (211) of the flexible section of pipe (21) and provided at its free end with the coupling system (5), the transfer system comprising suspension means configured for rigidly suspending, at the location of a first end thereof, the rigid section of pipe (22) from the outer branch (43) via articulation means permitting rotation around a vertical axis and at least one horizontal axis.

The structure comprises a hull extending longitudinally along a longitudinal hull axis, a mooring equipment, comprising a first group of mooring lines connected to an anchor on the bottom of the body of water, the mooring lines of the first group protruding laterally beyond a first side of the hull, opposite the second side of the hull. The mooring equipment comprises a second group of mooring lines protruding laterally beyond the second side, and connected to an anchor located away from the second side on the bottom of the body of water. The mooring lines of the first group are connected on the first side of the hull, the space facing a second lateral wall of the hull being free of mooring lines.

The structure comprises a hull extending longitudinally along a longitudinal hull axis, a mooring equipment, comprising a first group of mooring lines connected to an anchor on the bottom of the body of water, the mooring lines of the first group protruding laterally beyond a first side of the hull, opposite the second side of the hull. The mooring equipment comprises a second group of mooring lines protruding laterally beyond the second side, and connected to an anchor located away from the second side on the bottom of the body of water. The mooring lines of the first group are connected on the first side of the hull, the space facing a second lateral wall of the hull being free of mooring lines.

A system and method by which energy from ocean waves is converted into hydrogen, and that hydrogen is used to manifest electrical and mechanical energies by an energy consuming device. A portion of the generated electrical power is communicated to water electrolyzers which produce oxygen and hydrogen from water as gases. At least a portion of the generated hydrogen gas is transferred to a transportation ship via a hose-carrying, remotely operated (or otherwise unmanned) vehicle, and subsequently transferred to an energy-consuming module or infrastructure, where a portion of the hydrogen is consumed in order to manifest a generation of electrical energy, a mechanical motion, and/or a chemical reaction.

An autonomous loading/unloading system and method for transferring material includes: a buoy for releasing onto water; a messenger line coupled to the buoy for being pulled; a carrier line loop coupled to the messenger line for being pulled, where a payload is coupled to the carrier loop for transferring the material to or from an unmanned ship; a fetch/release platform to fetch or release the payload from or onto the water; a loading/unloading dock for the payload; a plurality of line guides for guiding the carrier loop; and a platform-to-payload interconnect for autonomous loading or unloading of the material from/to the payload.

The disclosure includes embodiments of systems, methods, and a kit to monitor remotely operational conditions of a pump engine and a pump mounted on a marine barge during offloading operation of barge petroleum product contents. According to an embodiment, a marine barge monitoring system may include a housing connected to the marine barge in a position to monitor the pump engine and the pump and having an electronic assembly positioned in the housing. The marine barge monitoring system also may include one or more sensors communicatively connected to the relay control module via the input/output module; a status monitoring and communication device communicatively connected to the relay control module; a warning indicator connected to the electronic assembly; and one or more remotely positioned monitoring servers having a memory positioned remote from the marine barge and in communication with the status monitoring and communication device.