A method for generating an insulating vacuum in a container is provided. The method includes evacuating air from a space between double walls of the container for a first predetermined time period. The method also includes after the first predetermined time period, if a vacuum level within the space has not reached a first predetermined vacuum level, purging the space by supplying a gas into the space and subsequently evacuating the air from the space for a period of time equal to the first predetermined time period. The method also includes repeating the evacuating and purging until the vacuum level within the space reaches the first predetermined vacuum level. The method also includes when the vacuum level within the space reaches the first predetermined vacuum level, evacuating the air from the space for a second predetermined time period.

The present disclosure discloses a method for simulating performance and optimizing design of an LNG ambient air vaporizer under a frosting condition, performing site operation test on the LNG ambient air vaporizer to obtain fitting relationship between the outer wall temperature of frosted finned tube and frost layer; transforming a sum of increased frost layer thermal resistance and thermal resistance into equivalent thermal contact resistance, and representing the equivalent thermal contact resistance as a function of the outer wall temperature; establishing a calculation model of the LNG ambient air vaporizer, performing simulation calculation by equivalent heat conduction coefficient, so as to obtain fluid-solid conjugate heat transfer characteristics and vaporization performance of the LNG ambient air vaporizer under the frosting condition for optimization design of the LNG ambient air vaporizer.

A system for recalibrating a temperature reading of a dewar includes a vapor plug and an electronic device. The vapor plug includes a vapor plug cover, a neck extending from the vapor plug cover, and a sensor positioned on the neck. The neck is configured to be inserted into an opening of the dewar. The sensor is configured to detect at least one parameter associated with the dewar. The electronic device is in communication with the sensor, and is configured to receive, recalibrate, and transmit the at least one parameter from the sensor.

A method for filling a fluid container with a cryogenic fluid, the method including the step of reducing with a container temperature reducer a container temperature of the fluid container prior to adding the cryogenic fluid to the fluid container. The method can include additional steps, including: compressing with a compressor the cryogenic fluid based at least partially on the container temperature, controlling with a controller the extent that the compressor compresses the cryogenic fluid, cooling with a fin pack the cryogenic fluid, filtering with a filter the cryogenic fluid, analyzing with a fluid analyzer a fluid within the cryogenic fluid, monitoring with a water monitor a water content of the cryogenic fluid and/or monitoring with a fluid sensor a fluid property of the cryogenic fluid.

Provided are a gas processing system, a control method thereof, and an electrical device. The gas processing system includes: a gas storage container, a controller, and a switch component. The gas storage container has a first gas flow branch configured for communicating with a battery box and supplies a dry gas to the battery box. The controller can acquire a state parameter of a gas in the battery box. The switch component is arranged on the first gas flow branch and can switched between a first state, in which the first gas flow branch is turned on, and a second state, in which the first gas flow branch is blocked. The controller is in communication connection with the switch component, and can control the switch component to be switched from the second state to the first state when the state parameter of the gas acquired satisfies a preset condition.

A control conduit for liquid hydrogen offloading is configured to couple a controller of a liquid hydrogen offload system to a liquid hydrogen tanker. The control conduit includes a control line and a gas detector. The control line is configured to transmit a control signal from the controller to the liquid hydrogen tanker. The gas detector is configured to detect hydrogen gas and provide a gas detector signal to the controller. The gas detector is secured to the control line at a predetermined distance from a tanker connection end of the control line.

A system to detect moisture level in a compressed gas cylinder includes a gas vent/fill line configured to be in fluid communication with a compressed gas cylinder; a vacuum system with a vacuum line and a vacuum pump connected to the vacuum line; and a dewpoint monitor connected to a dewpoint line and the vacuum line. When a compressed gas cylinder is connected to the gas vent/fill line, the vacuum pump draws gas from the gas vent/fill line into the vacuum line and the dewpoint line, and into the dewpoint monitor, where the dewpoint monitor measures moisture content in compressed gas.

A method for generating an insulating vacuum in a container is provided. The method includes evacuating air from a space between double walls of the container for a first predetermined time period. The method also includes after the first predetermined time period, if a vacuum level within the space has not reached a first predetermined vacuum level, purging the space by supplying a gas into the space and subsequently evacuating the air from the space for a period of time equal to the first predetermined time period. The method also includes repeating the evacuating and purging until the vacuum level within the space reaches the first predetermined vacuum level. The method also includes when the vacuum level within the space reaches the first predetermined vacuum level, evacuating the air from the space for a second predetermined time period.

Systems and methods provide a self-contained sealed apparatus that captures, filters, compresses and stores methane gas produced by the decomposition of bio-degradable organic materials. The system includes a rotatable and sealable chamber with an intermittent drive unit that mixes moist bio-degradable material during an anaerobic reaction, and captures methane gas generated by anaerobic decomposition. A filter to remove impurities, a low-pressure storage tank, a compressor and a high-pressure storage tank are interconnected and controlled by a system that monitors system parameters, that may include gas flow rate, temperature, and gas volume, and controls system parameters, that may include drive unit activation, generator operation, and compressor operation.

A purge container (1) has a container body (21) having an interior space (20) for accommodating a submersible pump (2), an upper lid (23) configured to cover an upper opening of the container body (21), a lower lid (24) configured to cover a lower opening of the container body (21), and a purge-gas inlet port (27) and a purge-gas outlet port (28) communicating with the interior space (20) of the container main body (21). The container body (21) is secured to an upper portion of a pump column (3) in which the submersible pump (2) is to be installed.