This invention relates to a novel method and system for dispensing CO2 vapor without over pressurization. The system includes one or more liquid containers and one or more vapor containers. The system is designed to operate in a specific manner whereby a restricted amount of CO2 liquid is permitted into the vapor container through a restrictive pathway that is created and maintained by a shuttle valve during the filling operation so that equalization of container pressures is achieved, thereby allowing shuttle valve to reseat when filling has stopped. During use, a pressure differential device is designed to specifically isolate the vapor container from the liquid container so as to preferentially deplete liquid CO2 from the vapor container and avoid over pressurization of the system until the vapor container. The system is operated so that at least 50% of the CO2 product is dispensed from the vapor container. The system also includes novel control methodology for performing pre-fill integrity checks to ensure safety of subsequent dispensing of CO2 liquid from a source vessel to the onsite CO2 containers.

An inactive gas introducing facility for a storage rack is provided in which supply of inactive gas to a container is stopped if an open state of an inspection door is detected while in a normal stop state in which a stop nullifying command is not issued and in which the supply of the inactive gas based on the immediately preceding supply pattern is continued and any changes, through manual operation, to a parameter that defines the immediately preceding supply pattern are prohibited, if an open state of an inspection door is detected while in a stop nullifying state in which the stop nullifying command is issued.

An aseptic liquid cryogen dosing head has a liquid cryogen reservoir in communication with a dosing outlet. An electromagnetic actuator is attached to an upper end of a dosing valve stem and is operable to move the dosing valve stem to open and close the dosing outlet. An air-tight seal extends about the dosing valve stem and separates the liquid cryogen reservoir from a cavity between the seal and the electromagnetic actuator. A controller is operable to perform a head leakage test, including pressurizing the cavity with a pressure higher than a pressure within the reservoir, to check for leakage past the seal; and pressurizing the reservoir to check for leakage from the liquid cryogen reservoir.

A doser for dispensing a cryogenic fluid includes a doser body configured to receive the cryogenic fluid. The dosing arm has a proximal end and a distal end and a central passage extending between the proximal and distal ends. Furthermore, the dosing arm is configured to receive cryogenic fluid from the doser body. A bayonet connection removably connects the proximal end of the dosing arm to the doser body. A dosing head is mounted to the distal end of the dosing arm and is configured to receive cryogenic fluid from the central passage of the dosing arm and to dispense the cryogenic fluid.

This invention relates to a novel method and system for dispensing CO2 vapor without over pressurization from a system having multiple containers. The system includes one or more liquid containers and one or more vapor containers. The system is designed to operate in a specific manner whereby a restricted amount of CO2 liquid is permitted into the vapor container through a restrictive pathway that is created and maintained by a shuttle valve during the filling operation so that equalization of container pressures is achieved, thereby allowing shuttle valve to reseat when filling has stopped. During use, a pressure differential device is designed to specifically isolate the vapor container from the liquid container so as to preferentially deplete liquid CO2 from the vapor container and avoid over pressurization of the system until the vapor container becomes liquid dry. The system can be operated so that at least 50% of the CO2 vapor product is dispensed from the vapor container.

A storage facility includes a controller for monitoring a supply state of the inactive gas for the plurality of storage sections and for controlling the plurality of supply amount adjusting devices. The controller is configured to monitor the supply state of the inactive gas for the plurality of storage sections by dividing the plurality of storage sections into a plurality of monitoring areas, and to control a plurality of supply amount adjusting devices such that the supply state of the inactive gas supplied to the storage sections belonging to each of the plurality of monitoring areas satisfies a set restricting condition defined in advance.

A testing system connected to a gas cylinder and includes a pressure detector, a temperature detector, and a controller. The pressure detector is configured to detect a pressure of a stored gas in the gas cylinder. The temperature detector is configured to detect a temperature of the stored gas in the gas cylinder. The controller is configured to calculate variations in the pressure and the temperature of the stored gas and to determine whether a stored state of the stored gas is present within a predetermined range according to the variances in the pressure and the temperature of the stored gas.

An aseptic liquid cryogen dosing head has a liquid cryogen reservoir in communication with a dosing outlet. An electromagnetic actuator is attached to an upper end of a dosing valve stem and is operable to move the dosing valve stem to open and close the dosing outlet. An air-tight seal extends about the dosing valve stem and separates the liquid cryogen reservoir from a cavity between the seal and the electromagnetic actuator. A controller is operable to perform a head leakage test, including pressurizing the cavity with a pressure higher than a pressure within the reservoir, to check for leakage past the seal; and pressurizing the reservoir to check for leakage from the liquid cryogen reservoir.

A dispensing system for filling and refilling user propane tanks comprised of a point of purchase payment system with interactive display. Each purchased propane tank is filled at an access point within the dispensing unit for users to retrieve their order. A secondary payment method involves the use of a mobile app to purchase propane tanks and propane. A docking area takes both new tanks and tanks that need refilling. When refilling a propane tank, the user inserts the propane tank into the docking area. The propane tank is mechanically filled and inspected with cameras for damage and a leak test is conducted returned to the original docking area for the user to retrieve. The final amount on the customer invoice is based on the actual quantity of propane delivered into the user tank. The system also includes an autofill nozzle and autofill valve for application such as RVs.