A gas cylinder monitoring device (34) for use with a valve (18) for controlling the flow of gas from a cylinder (14). The valve (18) has a valve body (20), and the device comprises an ambient temperature sensor (38) to measure the ambient temperature (TA), a valve body temperature sensor (36) to measure the temperature (TV) of the valve body, and a processor (42). The processor (42) operates to process a compensated temperature (CT) calculated from the difference between the measured valve body temperature (TV) and the ambient temperature (TA) over time (t). A flow-rate (FR) of the flow of gas from the cylinder and/or the pressure (P) on the gas is determined.

A hight-pressure composite vessel comprising a casing fabricated through blow-moulding a preform of thermoplastic, a connection pipe fitting. In the connection connection pipe fitting (3) with a retaining collar (7), opposite to a sealing groove (9) designed for an o-ring seal, there is a groove (10) for a seeger to mount a non-detachable collar (11a) of the preform (11) by way of the seeger (10a). A method of manufacturing the high-pressure composite vessel under which the casing of the vessel is fabricated of a perform that is blow-moulded so as to obtain the required dimensions thereof, whereas the preform of a thermoplastic material is fabricated using any technology; and the casing of the vessel is connected with the connection pipe fitting, and the external surface of the vessel re reinforced by a special composite layer. The preform (11) first undergoes a process of controlled crystallization and, then, the ring-shaped groove (11b) is made in the collar (11a) of the preform (11).

A system and device for monitoring the content of a gas/liquid or gas only containment vessel such as a cylinder is provided. The disclosed apparatus is easily affixed to a standard gas cylinder and configured to monitor the pressure of the cylinder contents and activate a visual and/or audio alarm when the contents of the gas/liquid cylinder are no longer in a liquid or partially liquid state as well as activate another visual and/or audio alarm at a prescribed pressure when the contents of the cylinder are nearing depletion.

The present invention relates to an apparatus for controlling, measuring and reporting a physical quantity, more specifically to an apparatus that can be adapted to any valve of a container containing a fluid under pressure, more particularly a device that can be adapted to any valve of a container containing a gas or liquid under pressure. It has a particularly advantageous application in the general field of measuring the pressure of the output flow of fluid, in particular industrial or medicinal fluids contained in bottles. The machine comprises the support, electromechanical switch constituted by the dosing knob and the support for the dosing knob which incorporates the electronic circuitry for controlling the rate of fluid flow by pressure sensor for reading the output pressure of the fluid from the container and by the data processing system for processing the data obtained by the electromechanical switch and by the pressure sensor. This information can be viewed on the display or remotely transmitted.

A cryogenic medical device for delivery of subcooled liquid cryogen to various configurations of cryoprobes is designed for the treatment of damaged, diseased, cancerous or other unwanted tissues. The device is a closed or semi-closed system in which the liquid cryogen is contained in both the supply and return stages. The device is capable of generating cryogen to a supercritical state and may be utilized in any rapid cooling systems. As designed, the device comprises a number of parts including a vacuum insulated outer dewar, submersible cryogen pump, baffled linear heat exchanger, multiple pressurization cartridges, a return chamber, and a series of valves to control the flow of the liquid cryogen. The cryogenic medical device promotes the subcooling to any external cryogenic instrument.

A method for making a container for retaining anesthetic agent. The method includes creating two or more parts each having a mating surface, where the container is formed when the mating surfaces of the two or more parts are coupled together, and where a first part of the two or more parts is formed of a material having pores defined within the mating surface thereof. The method further includes processing the mating surface of the first part via friction stir welding to reduce the pores defined therein. The method further includes coupling the two or more parts together such that the mating surfaces contact to create the container configured to retain the anesthetic agent therein.

A storage tank for cryogenic liquid having an outer tank constructed of a rigid material and an inner tank contained within and spaced inwardly from the outer tank. A first fill line for cryogenic liquid has a first end open exteriorly of the outer tank and a second end open inside the inner tank. The first fill line is fluidly sealed to both the inner tank and the outer tank and the first fill line has a first predetermined flow rate at a set filling pressure. A valve is associated with the first fill line to selectively open and close the first fill line. A second fill line for cryogenic liquid has a first end open exteriorly of the outer tank and a second end open inside of the inner tank. The second fill line has a second predetermined flow rate at the predetermined filling pressure. Furthermore, the first and second lines are sized so that the first flow rate is several times the second flow rate.

A method for using CO.sub.2 as a contrast material in medical imaging procedures is disclosed. The method includes providing a source of pressurized CO.sub.2. The step of providing includes connecting the source of pressurized CO2 to a compressed gas unit for controlling delivery of the CO.sub.2. The method also includes regulating pressure of the CO.sub.2 delivered by the compressed gas unit, transmitting the pressurized CO.sub.2 from the compressed gas unit to a control valve assembly for delivery to a patient in controlled dosages, and sequentially processing the CO.sub.2 with the control valve assembly and delivering the CO.sub.2 to the patient as a contrast media.

A cryogenic gas manifold for use in a cryogenic gas system includes first and second interchangeable tubular headers. Each of the tubular headers has a nipple for receiving cryogenic gas from a source or for providing such cryogenic gas to a user. Each of the tubular headers has opposed branch nipples for threadedly receiving devices that interconnect at least certain of the branch nipples of the pair of tubular headers. This interconnection is by threaded engagement of at least certain devices such as regulators, valves, gauges, sensors, bypass valves, low-temperature shutoff valves, and the like. The interconnection of these various devices with the pair of headers establishes a structural integrity for the manifold. Feet may be clamped to the bottom of each of the headers to allow the manifold to be freestanding. The threaded engagement of all of the various elements with the header allows not only for fast assembly, but also for disassembly, making the manifold cost-effective.

A gas cylinder monitoring system (10) for monitoring the contents of a gas cylinder in an EMS vehicle (50) including a gas cylinder (12) for receiving and distributing gas therein, an individual cylinder monitoring system (14) operable to monitor data associated with the gas cylinder (12) and having a cylinder monitoring transmitter (16) operable to broadcast the data, and at least one receiving station (60,70) having a receiver (18,20) operable to receive the data from the individual cylinder monitoring system (14) and indicate if the contents of the gas cylinder (12) are below a pre-determined threshold and require replacing.