A method for handling of hydrocarbons on an offshore platform 14, 16 includes the absence of emergency depressurisation for a fire. The method comprises: arranging the platform 14, 16 such that there is no mechanism for emergency depressurisation of a hydrocarbon inventory of the platform 14, 16 in the event of a fire; restricting the size of the platform 14, 16 such that evacuation of personnel can be achieved prior to escalation of a fire due to the lack of emergency depressurisation; and permitting a fire to escalate by combustion of the hydrocarbon inventory after evacuation of the personnel.

[Problem] To efficiently transport an energy source such as electricity from a power generation facility to a reception facility without using a power transmission cable.

[Solution] An energy transportation system 100 comprises: a transportation ship 10 provided with a holding means for an energy source; a power generation facility 20 that supplies the energy source to the holding means of the transportation ship 10; and a reception facility 30 that receives the energy source supplied from the holding means of the transportation ship 10. Examples of the energy source held in the holding means of the transportation ship 10 include electricity and hydrogen.

A catamaran oil production apparatus is disclosed for producing oil in a marine environment. The apparatus includes first and second vessels that are spaced apart during use. A first frame spans between the vessels. A second frame spans between the vessels. The frames are spaced apart and connected to the vessels in a configuration that spaces the vessels apart. The first frame connects to the first vessel with a universal joint and to the second vessel with a hinged connection. The second frame connects to the second vessel with a universal joint and to the first vessel with a hinged or pinned connection. At least one of the frames supports an oil production platform. One or more risers or riser pipes extends from the seabed (e.g., at a wellhead) to the production platform (or platforms). In one embodiment, the production apparatus includes crew quarters.

The invention relates to a system for the storage and production of electrical energy in a marine environment, wherein at least one ballast is lowered from a high position to a low position and then raised, by means of at least one cable (115) connected to a barge or platform (110). The barge comprises a generator/motor (113) actuated by the cable or actuating same. The ballasts (107, 108) are secured to a partially floating element (106) which is itself connected, by a retaining cable (105), to an element (101) floating on the surface and provided with means for varying the length of said retaining cable (105), the partially floating element (106) comprising a volume of gas compressible according to the surrounding pressure.

A subsea fluids storage facility comprises a tank for holding and separating fluids which is equipped with ballast capacity and a separable base to be deployed upon the seabed in shallow or deep water, and the storage facility is connectable to a surface production facility, especially a buoy for processing fluids. In deep water the tank is held at a depth above the base for temperature controlled stabilization of produced oil in the tank.

An LNG production plant and a method of constructing the LNG production plant is disclosed. The LNG production plant includes at least one plant module and a support structure to support the plant module. Each plant module is dry transported by a heavy lift vessel and subsequently transferred to the support structure without lifting the plant module from a deck of the vessel. The support structure includes a landing substructure onto which the plant module is transferred from the vessel. Landing substructure may be onshore or offshore. The support structure may also include one or more onshore support substructures and a transfer path enabling a plant module to be moved from the landing substructure to a corresponding onshore support substructure.

A petroleum drilling, production, storage and offloading vessel having a hull, a main deck, an upper cylindrical side section extending downwardly from the main deck, an upper frustoconical side section, a cylindrical neck section, a lower ellipsoidal section that extends from the cylindrical neck section, and a fin-shaped appendage secured to a lower and an outer portion of the exterior of a bottom surface. The upper frustoconical side section located below the upper cylindrical side section and maintained to be above a water line for a transport depth and partially below the water line for an operational depth of the petroleum drilling, production, storage and offloading vessel.

A buoyant offshore structure, comprising a hull element (6a) having an inner space (10), a surface end (12) and an underwater end (14); and at least one storage tank (15a) for liquid, extending from the surface end (12) of the hull element into the inner space (10), wherein the storage tank is removable from the inner space by lifting from the hull element's surface end.

Embodiments disclosed herein include a vessel for floating and traveling adjacent to an upper surface of a body of water. In an embodiment, the vessel comprises a support structure, a first floatation chamber coupled to the support structure, a second floatation chamber coupled to the support structure, the second floatation chamber laterally spaced apart from and fluidly coupled to the first floatation chamber, and a third floatation chamber coupled to the support structure, the third floatation chamber laterally spaced apart from the first floatation chamber and from the second floatation chamber. In an embodiment, the vessel further comprises a robot system coupled to the support structure, where the robot system comprises an end effector and a nozzle head coupled to the end effector.

Embodiments disclosed herein include a vessel for floating and traveling adjacent to an upper surface of a body of water. In an embodiment, the vessel comprises a support structure, a first floatation chamber coupled to the support structure, a second floatation chamber coupled to the support structure, the second floatation chamber laterally spaced apart from and fluidly coupled to the first floatation chamber, and a third floatation chamber coupled to the support structure, the third floatation chamber laterally spaced apart from the first floatation chamber and from the second floatation chamber. In an embodiment, the vessel further comprises a robot system coupled to the support structure, where the robot system comprises an end effector and a nozzle head coupled to the end effector.