A modular fuel tank assembly includes a first fuel tank body defining a first inner volume and a second fuel tank body defining a second inner volume, where the first inner volume is spatially separate from the second inner volume. A connecting conduit is in fluid communication with the first fuel tank and the second fuel tank. The first fuel tank, the second fuel tank and the connecting conduit each define a double-walled structure having an inner wall and an outer wall spaced apart from the inner wall.

A modular fuel tank assembly includes a first fuel tank body defining a first inner volume and a second fuel tank body defining a second inner volume, where the first inner volume is spatially separate from the second inner volume. A connecting conduit is in fluid communication with the first fuel tank and the second fuel tank. The first fuel tank, the second fuel tank and the connecting conduit each define a double-walled structure having an inner wall and an outer wall spaced apart from the inner wall.

The embodiments of the present disclosure provide a method and an apparatus for providing vehicle information, a device and a storage medium for implementing the method. The method includes: acquiring a first time period expected for a first vehicle to wait before supplement of energy for the first vehicle is to be commenced; determining a second time period expected to be required during the supplement of the energy for the first vehicle based on an amount of the energy to be supplemented for the first vehicle; determining a third time period expected to require for completing the supplement of the energy for the first vehicle based on the first time period and the second time period; and providing the third time period.

A system comprising an ammonia cracking unit in which ammonia is split into hydrogen and nitrogen and a hydrogen fueling station for fueling of vehicle tanks with hydrogen from the ammonia cracking unit which comprises gas operated valves (GOVs), one or more hydrogen compressing units wherein the hydrogen from the ammonia cracking unit is compressed, and one or more dispensing units for dispensing the compressed hydrogen to vehicle tanks which each comprise a nozzle through which the hydrogen is passed to the vehicle tank, wherein nitrogen from the ammonia cracking unit is used in e.g.: the operation of one or more of the GOVs; for blanketing one or more of said hydrogen compressing units; for blanketing and/or purging one or more of the dispensing units; for drying one or more of the nozzles between uses to prevent nozzle freeze on.

A system comprising an ammonia cracking unit in which ammonia is split into hydrogen and nitrogen and a hydrogen fueling station for fueling of vehicle tanks with hydrogen from the ammonia cracking unit which comprises gas operated valves (GOVs), one or more hydrogen compressing units wherein the hydrogen from the ammonia cracking unit is compressed, and one or more dispensing units for dispensing the compressed hydrogen to vehicle tanks which each comprise a nozzle through which the hydrogen is passed to the vehicle tank, wherein nitrogen from the ammonia cracking unit is used in e.g.: the operation of one or more of the GOVs; for blanketing one or more of said hydrogen compressing units; for blanketing and/or purging one or more of the dispensing units; for drying one or more of the nozzles between uses to prevent nozzle freeze on.

A fuel distribution station includes a first fuel tank for releasably holding a first fuel, and a second fuel tank for releasably holding a second fuel. A connection member extends between the first fuel tank and the second fuel tank, and provides a rigid connection between the first fuel tank and the second fuel tank. A support structure supports the first fuel tank and the second fuel tank in an elevated position a predetermined distance above ground, sufficient to allow for passage of land vehicles beneath the support structure during a fueling operation. A control system is utilized for selectively permitting and monitoring a discharge of fuel from the first fuel tank and the second fuel tank to the land vehicles during the fueling operation.

A fuel distribution station includes a first fuel tank for releasably holding a first fuel, and a second fuel tank for releasably holding a second fuel. A connection member extends between the first fuel tank and the second fuel tank, and provides a rigid connection between the first fuel tank and the second fuel tank. A support structure supports the first fuel tank and the second fuel tank in an elevated position a predetermined distance above ground, sufficient to allow for passage of land vehicles beneath the support structure during a fueling operation. A control system is utilized for selectively permitting and monitoring a discharge of fuel from the first fuel tank and the second fuel tank to the land vehicles during the fueling operation.

A hydrogen supply system includes: a facility identification unit that identifies a fuel supply facility in the vicinity of a travel route of a vehicle to a destination; a calculation unit that calculates an estimated remaining amount of hydrogen fuel at an arrival time when the vehicle reaches the fuel supply facility on the basis of remaining amount information indicating a remaining amount of the hydrogen fuel transmitted from the vehicle; a determination unit that determines whether or not refueling of the vehicle is required on the basis of the estimated remaining amount; and a registration unit that registers an estimated replenishment amount based on the estimated remaining amount and the arrival time as a usage reservation at the fuel supply facility in a case in which the determination unit determines that the refueling is required.

The present disclosure relates to systems and methods for optimizing refueling hydrogen in vehicles. Specifically, the present disclosure relates to identifying a refueling station, conducting a safety check on the vehicle based on a distance between the vehicle and the refueling station, switching a power source of the vehicle to only be a battery, swapping an empty or partially filled hydrogen fuel tank on the vehicle with a filled or partially filled hydrogen fuel tank at the refueling station, and switching the power source of the vehicle to include a hydrogen power source.

The present disclosure relates to systems and methods for optimizing refueling hydrogen in vehicles. Specifically, the present disclosure relates to identifying a refueling station, conducting a safety check on the vehicle based on a distance between the vehicle and the refueling station, switching a power source of the vehicle to only be a battery, swapping an empty or partially filled hydrogen fuel tank on the vehicle with a filled or partially filled hydrogen fuel tank at the refueling station, and switching the power source of the vehicle to include a hydrogen power source.