A watercraft has a hull having a keel, a deck supported by the hull, and a compartment defined between the hull and the deck. A fuel reservoir is disposed in the compartment and extends longitudinally over the keel. The fuel reservoir has an external hollowed portion. At least one battery is at least partially disposed in the external hollowed portion.

A watercraft has a hull having a keel, a deck supported by the hull, and a compartment defined between the hull and the deck. A fuel reservoir is disposed in the compartment and extends longitudinally over the keel. The fuel reservoir has an external hollowed portion. At least one battery is at least partially disposed in the external hollowed portion.

The present invention relates to an arrangement for containment of liquid natural gas (LNG) in a hull compartment of a marine construction, comprising a self-supporting primary barrier, a second barrier surrounding the self-supporting primary barrier, and an access space between the self-supporting primary barrier and the secondary barrier. The self-supporting primary barrier is a liquid-tight self-supporting LNG tank and is connected with the hull compartment by support devices penetrating the secondary barrier. The secondary barrier is a liquid-tight thermal insulation connected with the interior surface of the hull and is sealed to the support devices by a flexible liquid tight seal, so that the self-supporting primary barrier and the secondary barrier are separately connected with the hull compartment to prevent transfer of forces between the primary barrier and the second barrier.

The present invention relates to an arrangement for containment of liquid natural gas (LNG) in a hull compartment of a marine construction, comprising a self-supporting primary barrier, a second barrier surrounding the self-supporting primary barrier, and an access space between the self-supporting primary barrier and the secondary barrier. The self-supporting primary barrier is a liquid-tight self-supporting LNG tank and is connected with the hull compartment by support devices penetrating the secondary barrier. The secondary barrier is a liquid-tight thermal insulation connected with the interior surface of the hull and is sealed to the support devices by a flexible liquid tight seal, so that the self-supporting primary barrier and the secondary barrier are separately connected with the hull compartment to prevent transfer of forces between the primary barrier and the second barrier.

The present disclosure relates to a method and device for optimizing navigation of a ship. The method according to an embodiment of the present disclosure may generate recommended navigation information about a navigation route of a ship, based on navigation plan information associated with a departure location and an arrival location of the ship, predict a boil-off gas (BOG) generation amount of the ship and a tank pressure value of the ship, based on the recommended navigation information, and obtain optimal navigation information associated with operation control of the ship, based on the BOG generation amount and the tank pressure value.

The invention relates to a Floating Production Storage and Offloading, FPSO-, or Floating Production Storage, FSO-, structure comprising a hull adapted to support a weight of at least 50.000 tons, preferably at least 70.000 tons, with sidewalls of a length L extending in a longitudinal direction, a bottom structure and an upper deck, the hull having a breadth B, a process unit support structure overlying the upper deck, hydrocarbon processing units mounted on the process unit support structure, an outer part of the hull comprising: side spaces being bounded by the bottom structure, the upper deck, a respective side wall and an adjacent longitudinal sidewall, the adjacent longitudinal sidewalls being situated at a distance Wt from the side walls, Wt being at least equal to the smallest of 0.2 B or 11.5 m, an inner part of the hull comprising: at least one hydrocarbon storage tank for storage of hydrocarbons being situated between the bottom structure, the upper deck and the adjacent longitudinal walls, wherein the vessel comprises a centre line bulkhead and, between one and four hydrocarbon storage tanks of substantially the same size extending, in a transverse direction, between an adjacent longitudinal sidewall and the centreline bulkhead.

According to some embodiments of the present disclosure, a low-profile cargo vessel includes a cargo bed that is open to the stern, an engine compartment forward of the cargo bed, a fairing, and buoyancy volume. The cargo bed includes a cargo bed floor and first and second cargo bed walls on opposite sides of cargo bed floor. The cargo bed, interior portions of the first and second cargo bed walls, and interior portions of cargo bed floor are free-flooding to sea water. The fairing is configured to provide a hydrodynamic bow structure ahead of the engine compartment. The buoyancy volume is inside upper portions of the first and second cargo bed walls spaced apart from cargo bed floor so that the low-profile cargo vessel floats with a waterline above the cargo bed floor and more than half way up the first and second cargo bed walls.

According to some embodiments of the present disclosure, a low-profile cargo vessel includes a cargo bed that is open to the stern, an engine compartment forward of the cargo bed, a fairing, and buoyancy volume. The cargo bed includes a cargo bed floor and first and second cargo bed walls on opposite sides of cargo bed floor. The cargo bed, interior portions of the first and second cargo bed walls, and interior portions of cargo bed floor are free-flooding to sea water. The fairing is configured to provide a hydrodynamic bow structure ahead of the engine compartment. The buoyancy volume is inside upper portions of the first and second cargo bed walls spaced apart from cargo bed floor so that the low-profile cargo vessel floats with a waterline above the cargo bed floor and more than half way up the first and second cargo bed walls.