An arrangement for a cryogenic system includes a cryogenic tank for storing a cryogenic liquid and a trycock pipe, which trycock pipe has a first end mechanically connected to the cryogenic tank. The trycock pipe includes a tube with a first end fluidly connected to the cryogenic tank for receiving cryogenic liquid from the cryogenic tank. The arrangement further includes a sensor measuring the temperature of the tube. The tube has a second free end opposite to the first end of the tube, which second free end is closed, and the temperature sensor is arranged outside the tube measuring the temperature at the second free end of the tube.

The invention is directed to a hand-wheel for adjusting an outlet pressure and/or a flow-rate of a tap for a gas cylinder, the hand-wheel comprising a body; and a transparent cover fixed on the body. The hand-wheel further comprises indicia arranged between the transparent cover and the body so as to be visible by a user but not in contact with the fingers of the user. The invention is also directed to a tap for gas cylinder, comprising such a hand-wheel, as well as to a tap assembly comprising such a tap and a cover housing the tap.

A device for supplying pressurized fluid including a pressurized fluid cylinder, at least one first tap connected to the pressurized fluid cylinder, the tap including an internal fluid circuit including an isolation valve, the device including an electronic apparatus for the wireless remote communication of data via electromagnetic waves, the electronic communication apparatus including a communication element designed to communicate wirelessly using at least one of the following frequency-modulation and/or phase-modulation low-consumption and long-range communication technologies: LoRa communication technology, communication technology from Sigfox, where the device includes a protective cap mounted on the cylinder in order to protect the first tap and a second tap connected detachably to the first tap, and the electronic communication apparatus being situated either on the cylinder, on the cap, on the first tap, or on the second tap.

Disclosed is a method for detecting leakage of a full-capacity liquefied natural gas (LNG) storage tank by acoustic emission. The method includes: detecting an amplitude of system noise by an acoustic sensor, and determining a signal acquisition threshold; acquiring an amplitude of ambient noise; acquiring an amplitude of the acoustic signal excited by the analog sound source at the distance of 0.1 m from the acoustic sensor and an amplitude of the acoustic signal excited by the analog sound source at the distance of x m from the acoustic sensor, and calculating, an attenuation coefficient of an acoustic signal passing through the outer wall of the storage tank; determining a maximum detection range of the acoustic sensor; and continuously moving the acoustic sensor on the outer wall of the storage tank in a step smaller than the maximum detection range, to perform an LNG leakage detection.

Disclosed is a device, a system and methods for tracking conductive composite pressurized gaseous storage tanks. The system including anchoring an RFID device in a non-conductive blind boss, wherein the anchor material has a low dielectric and has minimal reflection if RF energy.

An arrangement for a cryogenic system includes a cryogenic tank for storing a cryogenic liquid and a trycock pipe, which trycock pipe has a first end mechanically connected to the cryogenic tank. The trycock pipe includes a tube with a first end fluidly connected to the cryogenic tank for receiving cryogenic liquid from the cryogenic tank. The arrangement further includes a sensor measuring the temperature of the tube. The tube has a second free end opposite to the first end of the tube, which second free end is closed, and the temperature sensor is arranged outside the tube measuring the temperature at the second free end of the tube.

Disclosed is a device, system and methods for tracking conductive composite pressurized gaseous storage tanks. The system including anchoring an RFID device in a non-conductive blind boss. Wherein the anchor material has a low dielectric and has minimal reflection if RF energy.

A composite high-pressure vessel comprises a casing (1) made by blow molding a preform made of a thermoplastic material, a connection stub (3), a bottom dome (4) and a composite reinforcing coating made of a supporting braid (2) that consists of a bundle of filaments (5) embedded in resin, preferably containing nano-additives. At least one optical fiber (6) is embedded in at least one layer of the supporting braid (2), and its ends are led outside the composite reinforcing coating. The optical fiber (6) is led in a polar braid between the connection stub (3) and the bottom dome (4), at an angle of inclination to the vessel axis of 0-30. The optical fiber (6) may be additionally led in a hoop braid, with an angle a of inclination to the vessel axis of 45-90.

Hydrogen pressure vessel, comprising a shell with an internal volume; wherein: the pressure vessel is arranged for storing compressed hydrogen at a pressure greater than 200 bar; the shell is made of a steel having a yield strength (S.sub.y) of at least 355 MPa; and said shell is formed by a multitude of longitudinally extending segments, wherein each longitudinally extending segment has a circumferential wall, with a wall thickness (WT), defining an internal diameter (ID.sub.1), the multitude of longitudinally extending segments together forming the internal volume of the shell.