A crossover protection system including a product transport vehicle having a tank compartment for containing a liquid product, a fluid property sensor positioned to contact liquid product stored in the tank compartment, a system controller, and a valve coupled to the tank compartment. The valve regulates a flow of liquid product from the tank compartment and has a normally locked state. The system controller may compare a received transported liquid type signal from the fuel property sensor indicative of the type of liquid product in the tank compartment and compare the type of liquid product to a stored liquid product type. If the two types match, the crossover protection controller transitions the valve to an unlocked state to allow the liquid product to unload from the tank compartment. If the two types do not match, the crossover protection controller will disable the valve from transitioning to the unlocked state.

Some embodiments of the present invention provide Apparatus (100) comprising: a fluid inlet (105IN) for receiving fluid from a fluid source, a fluid outlet (105OUT) and a conduit (110) disposed therebetween; fluid inspection means (152) for inspecting a fluid within the conduit (110), the inspection means (152) being configured to provide an output indicative of a type of fluid in the conduit (110); valve means (120) operable selectively to prevent or allow flow of fluid through the conduit (110) from the fluid inlet (105IN) to the fluid outlet (105OUT); and control means (150) configured automatically to cause the valve means (120) to prevent or allow flow of fluid through the conduit (110) in dependence on the output of the fluid inspection means (152) and permitted fluid information, the permitted fluid information being information indicative of a type of fluid that is to be permitted to flow through the conduit (110), the apparatus (100) comprising an electrical generator (140) configured to generate electrical power to charge a charge storage device in response to flow of fluid through the apparatus (100) during an operation in which fluid flows from the fluid inlet (105IN) to the fluid outlet (105OUT) via the conduit (110), the charge storage device being arranged to provide a supply of electrical power for the apparatus.

A hydrogen gas supply system comprises a storing unit that stores hydrogen, a communication unit that receives at least either of burden information indicative of an environmental burden exerted during manufacturing of hydrogen externally received by the storing unit and quality information indicative of quality with respect to the hydrogen externally received by the storing unit, a user interface unit that provides an output in accordance with the at least either of the burden information and the quality information with respect to the hydrogen supplied from the storing unit to the user, and a controller that controls the user interface unit based on an amount of the hydrogen received by the storing unit and the at least either of the burden information and the quality information, which is received by the communication unit.

A hydrogen gas supply system comprises a storing unit that stores hydrogen, a communication unit that receives at least either of burden information indicative of an environmental burden exerted during manufacturing of hydrogen externally received by the storing unit and quality information indicative of quality with respect to the hydrogen externally received by the storing unit, a user interface unit that provides an output in accordance with the at least either of the burden information and the quality information with respect to the hydrogen supplied from the storing unit to the user, and a controller that controls the user interface unit based on an amount of the hydrogen received by the storing unit and the at least either of the burden information and the quality information, which is received by the communication unit.

Fuel dispenser (100) comprising: a fluid inlet (105IN) for receiving fuel from a fuel source, a fluid outlet (105OUT) and a conduit (110) disposed therebetween; inspection means (152) for inspecting the fuel within the conduit (110), the inspection means (152) being configured to provide an output indicative of a type of fuel in the conduit (110); valve means (120) operable selectively to prevent or allow flow of fluid through the conduit (110) from the fluid inlet (105IN) to the fluid outlet (105OUT); and control means (150) configured automatically to cause the valve means (120) to prevent or allow flow of fuel through the conduit (110) in dependence on the output of the fuel inspection means (152) and permitted fluid information, the permitted fluid information being information indicative of a type of fuel that is to be permitted to flow through the conduit (110), the apparatus (100) comprising an electrical generator (140) configured to generate electrical power to charge a charge storage device in response to flow of fluid through the apparatus (100) during an operation in which fluid flows from the fluid inlet (105IN) to the fluid outlet (105OUT) via the conduit (110), the charge storage device being arranged to provide a supply of electrical power for the apparatus.

A transportation vehicle having a data interface for transmitting data to a robot, wherein the transportation vehicle includes a controller that produces control signals for controlling the robot for a specified working task and transmits the control signals to the robot via the data interface. Also disclosed is a method for controlling a robot by a transportation vehicle.

Fuel dispenser (100) comprising: a fluid inlet (105IN) for receiving fuel from a fuel source, a fluid outlet (105OUT) and a conduit (110) disposed therebetween; inspection means (152) for inspecting the fuel within the conduit (110), the inspection means (152) being configured to provide an output indicative of a type of fuel in the conduit (110); valve means (120) operable selectively to prevent or allow flow of fluid through the conduit (110) from the fluid inlet (105IN) to the fluid outlet (105OUT); and control means (150) configured automatically to cause the valve means (120) to prevent or allow flow of fuel through the conduit (110) in dependence on the output of the fuel inspection means (152) and permitted fluid information, the permitted fluid information being information indicative of a type of fuel that is to be permitted to flow through the conduit (110), the apparatus (100) comprising an electrical generator (140) configured to generate electrical power to charge a charge storage device in response to flow of fluid through the apparatus (100) during an operation in which fluid flows from the fluid inlet (105IN) to the fluid outlet (105OUT) via the conduit (110), the charge storage device being arranged to provide a supply of electrical power for the apparatus.

A hydrogen gas supply system comprises a storing unit that stores hydrogen, a communication unit that receives at least either of burden information indicative of an environmental burden exerted during manufacturing of hydrogen externally received by the storing unit and quality information indicative of quality with respect to the hydrogen externally received by the storing unit, a user interface unit that provides an output in accordance with the at least either of the burden information and the quality information with respect to the hydrogen supplied from the storing unit to the user, and a controller that controls the user interface unit based on an amount of the hydrogen received by the storing unit and the at least either of the burden information and the quality information, which is received by the communication unit.

A crossover protection system including a product transport vehicle having a tank compartment for containing a liquid product, a fluid property sensor positioned to contact liquid product stored in the tank compartment, a system controller, and a valve coupled to the tank compartment. The valve regulates a flow of liquid product from the tank compartment and has a normally locked state. The system controller may compare a received transported liquid type signal from the fuel property sensor indicative of the type of liquid product in the tank compartment and compare the type of liquid product to a stored liquid product type. If the two types match, the crossover protection controller transitions the valve to an unlocked state to allow the liquid product to unload from the tank compartment. If the two types do not match, the crossover protection controller will disable the valve from transitioning to the unlocked state.

A device for controlling refueling of hydrogen includes one or more hydrogen refueling facilities for refueling a hydrogen-powered vehicle with hydrogen, and a controller that collects state information and control data of the hydrogen refueling facilities, performs artificial intelligence learning based on the state information and the control data, and controls operations of the hydrogen refueling facilities based on the learning result.