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 floating dockable liquefied natural gas supply station, comprising: a main hull, a bottom base and a positioning system. The bottom base comprises a base plate or at least two base plates. The base plate is securely connected to a lower lateral side of the main hull by means of a splicing securing system. Therefore, the main hull and the bottom base of the floating dockable liquefied natural gas supply station can be assembled in a modular manner. It is possible to individually construct the main hull and bottom base of the floating dockable liquefied natural gas supply station, and to then use a modular method for connecting and assembling same on the ocean or on land, thus being able to flexibly form various types and dimensions of supply station, allowing for docking transport vessels accommodating various loading capacities of liquefied natural gas (LNG), and reducing the construction cost thereof.

A system, methods, and apparatus for preventing receptacle overfilling are presented. The system can include a sensor member configured to couple with a receptacle and sense a material level within the receptacle, such as via a sight glass of the receptacle. The system can include a controller in operable communication with the sensor member and configured to instantiate the shutoff of material flow from a material dispensing system if a particular material level is detected by the sensor member. The system can include an intermediate member configured to relay communications between the sensor member and the controller. The intermediate member can be coupled to a fluid line and can further act as a holster for the sensor member, such as by facilitating the coupling of the sensor member to the intermediate member and/or the fluid line.

An input includes a specified fluid product to be transported, a specified volume transfer of the specified fluid product to a berth, and a target flow rate of the specified fluid product. A first allowable operating range for volume transfer and a second allowable operating range for flow rate are determined at least based on: the specified fluid product, an availability of meters for metering, an availability of loading arms for loading the specified fluid product to a ship located at the berth, and an availability of vapor combustion units for flaring. A control signal is transmitted to at least one of multiple valves to establish a flow path for the specified fluid product. A start signal is transmitted to initiate a recipe that controls flow through the flow path within the first allowable operating range and the second allowable operating range.

An input includes a specified fluid product to be transported, a specified volume transfer of the specified fluid product to a berth, and a target flow rate of the specified fluid product. A first allowable operating range for volume transfer and a second allowable operating range for flow rate are determined at least based on: the specified fluid product, an availability of meters for metering, an availability of loading arms for loading the specified fluid product to a ship located at the berth, and an availability of vapor combustion units for flaring. A control signal is transmitted to at least one of multiple valves to establish a flow path for the specified fluid product. A start signal is transmitted to initiate a recipe that controls flow through the flow path within the first allowable operating range and the second allowable operating range.

The invention relates to a system (1) for transferring liquefied gas between a first facility and a second facility, said transfer system (1) including: an articulated arm (2) including a first proximal part (6) suitable for being mounted so that it can rotate on the first facility about a first vertical axis (A), a second median part (7) that is mounted pivoting on the first proximal part (6) and a third distal part (8) that is mounted pivoting on the second median part (7); and at least one transfer line (3, 4, 5), suitable for transferring liquefied gas between the first facility and the second facility, and including a flexible first proximal portion (15) suitable for being connected to a liquefied gas storage tank of the first facility; a rigid second median portion (16) that is fastened to the second median part (7) of the articulated arm (2) and a third distal portion (17) that is suspended on the third distal part (8) of the articulated arm (2) and has an end suitable for being connected to a manifold of the second facility, the second median portion (16) being provided with a valve (22).

The invention relates to a system (1) for transferring liquefied gas between a first facility and a second facility, said transfer system (1) including: an articulated arm (2) including a first proximal part (6) suitable for being mounted so that it can rotate on the first facility about a first vertical axis (A), a second median part (7) that is mounted pivoting on the first proximal part (6) and a third distal part (8) that is mounted pivoting on the second median part (7); and at least one transfer line (3, 4, 5), suitable for transferring liquefied gas between the first facility and the second facility, and including a flexible first proximal portion (15) suitable for being connected to a liquefied gas storage tank of the first facility; a rigid second median portion (16) that is fastened to the second median part (7) of the articulated arm (2) and a third distal portion (17) that is suspended on the third distal part (8) of the articulated arm (2) and has an end suitable for being connected to a manifold of the second facility, the second median portion (16) being provided with a valve (22).

A sealed and thermally insulating storage tank for a fluid that is anchored in a load-bearing structure built into a ship, the ship having a longitudinal direction, the tank having a loading/unloading tower suspended from a ceiling wall of the load-bearing structure, the loading/unloading tower including first, second and third vertical pylons defining a prism of triangular section, the loading/unloading tower carrying at least a first pump, the tank having a support foot that is fastened to the load-bearing structure, the tank having at least one sump, the first pump being arranged outside the triangular prism and being aligned with the support foot in a first transverse plane that is orthogonal to the longitudinal direction of the ship.

A sealed and thermally insulating tank for storing a fluid, the tank being anchored in a load-bearing structure, the tank having a loading/unloading tower suspended from a ceiling wall of the load-bearing structure, the tank having a support foot that is fastened to the load-bearing structure in a zone of a bottom wall of the tank, the support foot being arranged to guide a vertical translational movement of the loading/unloading tower, the tank having at least one sump that is formed in the bottom wall of the tank, the bottom wall of the tank having a corrugated sealing membrane that is intended to be in contact with the fluid having at least first corrugations extending in a first direction and spaced apart from one another, the sump and the support foot are spaced apart by a distance at least three first corrugations pass between the sump and the support foot.

A sealed and thermally insulating tank for storing a fluid, the tank being anchored in a load-bearing structure, the tank having a loading/unloading tower suspended from a ceiling wall of the load-bearing structure, the tank having a support foot that is fastened to the load-bearing structure in a zone of a bottom wall of the tank, the support foot being arranged to guide a vertical translational movement of the loading/unloading tower, the tank having at least one sump that is formed in the bottom wall of the tank, the bottom wall of the tank having a corrugated sealing membrane that is intended to be in contact with the fluid having at least first corrugations extending in a first direction and spaced apart from one another, the sump and the support foot are spaced apart by a distance at least three first corrugations pass between the sump and the support foot.