A liquefied gas unloading and deep evacuation system may more quickly, more efficiently and more completely unload liquefied gases from transport tanks, such as rail cars, into stationary storage tanks or into truck tanks. The system may utilize a two stage compressor, an electric motor, a variable frequency drive, a four way valve, a three way valve, a two way valve, a programmable logic controller based control system and pressure and temperature transmitters. The valving enables deep evacuation of the transport or supply tank to more completely empty the transport tank. The programmable logic controller and variable speed drive may be used to variably control the speed of the two stage compressor so that the system may be running as fast as possible during changes in ambient temperature and/or different stages of offloading the liquefied gases without exceeding the compressor's horsepower limit.

A liquefied gas unloading and deep evacuation system may more quickly, more efficiently and more completely unload liquefied gases from transport tanks, such as rail cars, into stationary storage tanks or into truck tanks. The system may utilize a two stage compressor, an electric motor, a variable frequency drive, a four way valve, a three way valve, a two way valve, a programmable logic controller based control system and pressure and temperature transmitters. The valving enables deep evacuation of the transport or supply tank to more completely empty the transport tank. The programmable logic controller and variable speed drive may be used to variably control the speed of the two stage compressor so that the system may be running as fast as possible during changes in ambient temperature and/or different stages of offloading the liquefied gases without exceeding the compressor's horsepower limit.

A cryogenic railway tank car includes an outer tank, an inner tank positioned within the outer tank, an internal nozzle, and a pipe. The inner tank includes a shell that defines an opening. The internal nozzle is coupled to the inner tank at least along a perimeter of the opening and extends in a radial direction through the opening and into the inner tank. A space defined by an interior surface of the outer tank, an exterior surface of the inner tank, and an interior surface of the nozzle is configured to hold a vacuum. The pipe is configured to transport the fluid between an exterior of the outer tank and the interior of the inner tank. At least a portion of the pipe extends from the outer tank to the inner tank through at least a portion of the nozzle.

A liquefied gas unloading and deep evacuation system may more quickly, more efficiently and more completely unload liquefied gases from transport tanks, such as rail cars, into stationary storage tanks or into truck tanks. The system may utilize a two stage compressor, an electric motor, a variable frequency drive, a four way valve, a three way valve, a two way valve, a programmable logic controller based control system and pressure and temperature transmitters. The valving enables deep evacuation of the transport or supply tank to more completely empty the transport tank. The programmable logic controller and variable speed drive may be used to variably control the speed of the two stage compressor so that the system may be running as fast as possible during changes in ambient temperature and/or different stages of offloading the liquefied gases without exceeding the compressor's horsepower limit.

According to certain embodiments, an adapter assembly for a bottom outlet valve comprises an apparatus configured to be coupled to a stem of the bottom outlet valve of the railroad car. The stem of the bottom outlet valve is aligned generally with a longitudinal axis of the railroad car. The apparatus comprises a coupler configured to be coupled to the stem of the bottom outlet valve and a primary gear coupled to the coupler. The primary gear is configured to be coupled to a handle assembly extending from either side of the railroad car. The handle assembly is configured to operate the bottom outlet valve.

According to certain embodiments, an adapter assembly for a bottom outlet valve comprises an apparatus configured to be coupled to a stem of the bottom outlet valve of the railroad car. The stem of the bottom outlet valve is aligned generally with a longitudinal axis of the railroad car. The apparatus comprises a coupler configured to be coupled to the stem of the bottom outlet valve and a primary gear coupled to the coupler. The primary gear is configured to be coupled to a handle assembly extending from either side of the railroad car. The handle assembly is configured to operate the bottom outlet valve.

A liquefied gas unloading and deep evacuation system may more quickly, more efficiently and more completely unload liquefied gases from transport tanks, such as rail cars, into stationary storage tanks or into truck tanks. The system may utilize a two stage compressor, an electric motor, a variable frequency drive, a four way valve, a three way valve, a two way valve, a programmable logic controller based control system and pressure and temperature transmitters. The valving enables deep evacuation of the transport or supply tank to more completely empty the transport tank. The programmable logic controller and variable speed drive may be used to variably control the speed of the two stage compressor so that the system may be running as fast as possible during changes in ambient temperature and/or different stages of offloading the liquefied gases without exceeding the compressor's horsepower limit.

An operating mechanism for a bottom valve for a cargo tank of a railroad tank car, in which a valve operating lever is normally disconnected from a valve operating shaft and a valve operating shaft assembly includes a weak-link connector to prevent inadvertent opening of the bottom valve in case of derailment of the tank car.

A ball valve assembly for a railroad tank car is disclosed herein. The ball valve assembly may comprise a ball valve removably coupled to an end of a fittings flange of a railroad tank car, a dual thread retainer assembly affixed to an end of the ball valve opposite the fittings flange, and an anti-rotation assembly attached to the fittings flange. The dual thread retainer assembly may comprise a retainer affixed to the end of the ball valve opposite the fittings flange and a cap removably affixed to an end of the retainer opposite the ball valve. The anti-rotation assembly may comprise a base affixed to the fittings flange and a fork secured to the base that is configured to prevent rotation of the ball valve and the dual thread retainer assembly with respect to the fittings flange.

Disclosed herein is a logistics system and a method for the automatic transshipment of at least one fluid medium. The logistics system includes at least one transshipment site, wherein the transshipment site is configured to carry out at least one process selected from the group consisting of loading a mobile tank with the fluid medium and unloading the fluid medium from the mobile tank, where the transshipment site has at least one pipe system having at least one pipe connection, at least one controller, where the controller is programmed to control at least one function of the logistics system, at least one movement system having at least one movement arm and an automatic coupling system, where the movement arm is configured to move the coupling system, where the automatic coupling system is configured to automatically open at least one tank nozzle of the mobile tank, where the automatic coupling system is furthermore configured to automatically open the pipe connection of the transshipment site, and where the automatic coupling system is furthermore configured to fluidically connect the tank nozzle and the pipe connection.