A tank for a railway tank car includes an outer tank, a nozzle, a fittings plate, and a set of pipes. The nozzle protrudes through the outer tank such that an outer edge of the nozzle extends past an exterior surface of the outer tank. An intersection between the nozzle and the outer tank defines an opening in the outer tank. The fittings plate is welded to the nozzle around the outer edge of the nozzle. The set of pipes pass through the fittings plate and into the outer tank through the nozzle. The set of pipes includes pipes to load and/or unload fluid from the tank.

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.

Aspects and embodiments of inductively heated tank cars are described. In one embodiment, an inductive heating system includes an inductive heating module with a radially-curved pancake coil. The heating module can be positioned by an actuator assembly to inductively heat the contents of a tank car. In one example, the actuator assembly includes an assembly base including at least one base pole, an extension channel, and an extension actuator. The actuator assembly also includes an extension arm to retract into and extend out from the extension channel based on the extension actuator, an inductive heating module pivotally secured about an end of the extension arm, and a heating module lift actuator to lift the inductive heating module about the pivot at the end of the extension arm. By lifting and/or pivoting the inductive heating module, it can be positioned proximate to the tank car for inductive heat transfer.

A method of transporting natural gas by liquefaction of natural gas at ambient temperature, achieved by mixing the natural gas at high pressure with a hydrocarbon that is a stable liquid at ambient temperature and ambient pressure. The hydrocarbon liquid may be crude oil or a distillate of crude oil. The method includes: liquefaction: mixing the natural gas with the hydrocarbon liquid at an ambient temperature and a high pressure to generate a liquid mixture, which contains the natural gas dissolved in the hydrocarbon liquid; shipping: transporting the liquid mixture using a marine tanker, during which the liquid mixture is maintained at ambient temperature and the high pressure; and regasification: at the destination, releasing a gas from the liquid mixture by lowering the pressure of the liquid mixture. The hydrocarbon liquid may be used multiple times.

Aspects and embodiments of inductively heated tank cars are described. In one embodiment, an inductive heating system for tank cars includes a radially-curved pancake coil, a coil housing that surrounds at least a portion of the radially-curved pancake coil, and a frame structure comprising at least one attachment mechanism to secure the frame structure to an exterior surface of a tank car. The system can also include an induction heating power supply to supply power for inductively heating the tank car using the radially-curved pancake coil. When installed to the tank car, the coil housing is assembled with the frame structure to secure the radially-curved pancake coil to the exterior surface of the tank car. Any number of radially-curved pancake coils can be secured to the exterior surface of the tank car to heat the contents of the tank car through inductive heating.