A pressure vessel for storing high-pressure gas has a structure including: a nozzle body which is coupled to a vessel body that defines an inner wall surface of the pressure vessel, and has an inner flow path through which gas flows inside and outside of the pressure vessel; and a locker which is fastened to a lower portion of the nozzle body, and the structure is configured to provide dual sealing including sealing at an inclined surface by fastening force of the locker generated by an inclined pressing end of the locker, and sealing in the locker by sealing members.

The present invention relates to a curve-combined square pressure tank with which curves are combined so as to maintain internal high pressure, improve space efficiency, and reduce the weight thereof, and to a pressure tank, in which planes and curves are combined, formed by connecting flat plate members and curved members, having a plurality of aligned tension members for connecting the flat plate members facing each other, and having stress buffer parts formed at connection parts of the flat plate members and the curved members so as to enable internal pressure to be maintained.

To provide a fuel supply apparatus that can quickly supply hydrogen gas to a vehicle equipped with a plurality of large-capacity fuel tanks while observing a filling protocol. A fuel supply apparatus 100 according to the present invention including: a plurality of supply systems (101, 102); a supply control device (10, 20) provided in each of the supply systems (101, 102); a supply pipe (31, 41) communicating each of the supply systems (101, 102) and each of rear facilities (50, 60); a supply member (flow rate regulating valve 2, 12, etc.) interposed in the supply pipe (31, 41) and connected to each of the supply control devices (10, 20); and a supply hose (7, 17) connected to the supply pipe (31, 41), the supply hose (7, 17) having a supply nozzle (8, 18) at its tip, wherein the supply control device (10, 20) includes: a function of determining whether or not communication filling is established in one side of the supply system (101) and/or the other side of the supply system (102); and when communication filling is not established in the supply system (101) on the one side and communication filling is established in the supply system (102) on the other side, a function of supplying using vehicle side data in the supply system (102) on the other side.

A method for communicating regarding supply of hydrogen of a moving vehicle to one or more distribution stations begins by collecting at least two parameters relating to the vehicle during its movement by two or more sensors onboard the vehicle. The parameters include at least the current location of the vehicle. Next, the parameters are transmitted to a control module. At least one parameter relating to hydrogen available in the one or more distribution stations is then collected by another sensor, which then transmits the hydron availability parameters to the control module. A hydrogen distribution station is then identified while the vehicle is moving, and a user of the vehicle is informed of available hydrogen distribution stations and of hydrogen supply conditions in the identified distribution stations.

A reinforcement element, suitable for composite pressure vessel, may be configured to be inserted and to fill in a hollow shaft of a plastic liner of the composite pressure vessel, the hollow shaft connecting opposite walls of the liner. The reinforcement element may include a central part and two external parts constituted by a plurality of continuous fibres impregnated with a first resin. The central part of the reinforcement element may have a dimension substantially equal to the dimension of the hollow shaft and being a full part. The two external parts may be able to be unfolded and fixed on the external surface of opposite walls of the liner. A composite pressure vessel may include such a reinforcement element.

Disclosed are gas cylinder assemblies for containing pressurized gas. The gas cylinder assembly has a polymeric liner and a low-permeability barrier layer. The polymeric liner a first end portion, a second end portion and a central body. The central body comprises an outer surface and an inner surface disposed between the first end and the second end. The gas cylinder assembly comprises a reinforcement structure wound over the central body. The gas cylinder assembly further comprises a metal foil interposed between the reinforcement structure and central body. The metal foil is configured to reduce permeation of contents of the polymeric liner.

A mount for a double-walled vessel includes a first support to support the mount against an outer wall of the double-walled vessel, a second support to support the mount against an inner wall of the double-walled vessel, and a flexible member connecting the first support and the second support. The first support and can be arranged at a first end of the flexible member and the second support can be arranged at a second end of the flexible member opposite to the first end. Further described are a vessel including at least one such mount as well as a vehicle including such vessel.

A pressure vessel refueling system enables consistent mass flow rates and reduces the in-tank temperature rise caused by the heat of compression as gas is added to a vessel. The system includes a pressure vessel having a first gas inlet/outlet port and an interior cavity, and a nozzle is in fluid communication with the first gas inlet/outlet port. The nozzle and the pressure vessel are thermally coupled such that Joule-Thomson expansion of a gas flowing through the nozzle cools the interior cavity and contents of the pressure vessel.

A multi-vessel fluid storage and delivery system is disclosed which is particularly useful in systems having internal combustion engines which use gaseous fuels. The system can deliver gaseous fluids at higher flow rates than that which can be reliably achieved by vapor pressure building circuits alone, and that keeps pressure inside the storage vessel lower so that it reduces fueling time and allows for quick starts thereafter. The system is designed to store gaseous fluid in liquefied form in a plurality of storage vessels including a primary storage vessel fluidly connected to a pump apparatus and one or more server vessels which together with a control system efficiently stores a liquefied gaseous fluid and quickly delivers the fluid as a gas to an end user even when high flow rates are required. The system controls operation of the pump apparatus as a function of the measured fluid pressure, and controls the fluid pressure in a supply line according to predetermined pressure values based upon predetermined system operating conditions.

The present disclosure relates, according to some embodiments, to an intelligent compressed natural gas distributing system is inserted into an existing compressed natural gas fueling station. A means to distribute compress natural gas associated with designated primary dispenser as determined by fueling situations. The system maintains a high differential of pressure during fueling as to decrease time of fueling by means of control valves on the dispenser lines. Within the system, at least one of the dispenser line is determined to be the primary active dispenser and is fueled directly from a compressor when pressure is detected under optimal threshold. The subordinate lines are subject to a bypass in which fueling is directly sourced from a high-pressure storage and receiving excess gas from the primary active dispenser.