A gas supply marine vessel and a refueling facility are described. The gas supply marine vessel includes a hull with an upper deck having an elongated cargo cavity formed therein. Gas interface modules are disposed in the cavity and extend between hull sides, each module having a plurality of fuel vessel docking stations. A plurality of stacked fuel container assemblies are fluidically coupled to the docking stations. A gantry, is movable along the length of the cavity, straddles the cargo cavity between hull sides. An articulating crane is mounted on the gantry and it utilized to move fuel container assemblies to a fuel container depression formed in the deck of a floating refueling facility. The floating refueling facility includes a concave side to facilitate mooring adjacent a shoreline, the concave side forming angled extensions at corners of the deck with a linkspan extending from each of the angled extensions.

Various multifunctional dispensing systems with overhead fuel/air delivery and methods for using the same are provided. Such a system can include a dispenser system and an overhead delivery unit suspended on tracks above a vehicle drive aisle at a fueling station. The overhead delivery unit can include a fuel dispensing nozzle and an air dispensing nozzle that can be moved about the tracks so as to optimally position the nozzles to be approximately overhead the fuel doors and tires, respectively. Such an arrangement allows a customer to refuel their vehicle and inflate their tire(s) without moving their car between each transaction.

In a multi-part refueling device for refueling an electric drive battery or a fluid tank of a movable vehicle, simplified, reproducible refueling is to be achieved. The object is achieved in that the vehicle-side coupling device carried on the vehicle has connecting means designed as at least one charging coil, charging contacts or as a loading nozzle and also has a manipulator arm for descending, displacing and lowering the contact plate in a center of the stationary ground coupling device, wherein the manipulator arm comprises an upper arm segment pivotally and rotatably mounted on the vehicle side, a joint, a lower arm segment and a further joint for mounting the contact plate and is automatically controlled by the computer and control unit.

In a multi-part refueling device for refueling an electric drive battery or a fluid tank of a movable vehicle, simplified, reproducible refueling is to be achieved. The object is achieved in that the vehicle-side coupling device carried on the vehicle has connecting means designed as at least one charging coil, charging contacts or as a loading nozzle and also has a manipulator arm for descending, displacing and lowering the contact plate in a center of the stationary ground coupling device, wherein the manipulator arm comprises an upper arm segment pivotally and rotatably mounted on the vehicle side, a joint, a lower arm segment and a further joint for mounting the contact plate and is automatically controlled by the computer and control unit.

A system for confirming the identity of a vehicle. The device includes: a vehicle control unit in the vehicle to be identified; a vehicle identification device; an external service device designed to interact with the vehicle; a vehicle sensor in the vehicle; and an external sensor. The vehicle identification device establishes a data connection with the vehicle control unit and triggers a physical interaction between the vehicle control unit and the external service device. The vehicle sensor detects the physical interaction and transmits a corresponding vehicle detection value to the vehicle identification device. The external sensor detects the physical interaction and transmits a corresponding external detection value to the vehicle identification device; and the vehicle identification device compares the vehicle detection value and the external detection value with one another and confirms the identity of the vehicle if the two detection values coincide with one another within a predefined tolerance.

A system for confirming the identity of a vehicle. The device includes: a vehicle control unit in the vehicle to be identified; a vehicle identification device; an external service device designed to interact with the vehicle; a vehicle sensor in the vehicle; and an external sensor. The vehicle identification device establishes a data connection with the vehicle control unit and triggers a physical interaction between the vehicle control unit and the external service device. The vehicle sensor detects the physical interaction and transmits a corresponding vehicle detection value to the vehicle identification device. The external sensor detects the physical interaction and transmits a corresponding external detection value to the vehicle identification device; and the vehicle identification device compares the vehicle detection value and the external detection value with one another and confirms the identity of the vehicle if the two detection values coincide with one another within a predefined tolerance.

A system for electric vehicle charging and hydrogen fueling leverages existing infrastructure of a localized renewable energy microgrid and utilizes excess generated energy to power an electrolyzer to produce hydrogen gas on site that is compressed and stored in a pressure vessel. A first portion of the stored hydrogen gas may be used for hydrogen fueling of a fuel cell electric vehicle (FCEV) via a hydrogen fuel dispenser that is provided at a charging station. A second portion of the stored hydrogen gas may be converted into electricity through use of one or more fuel cells. The generated electricity may be used for charging a battery of a battery electric vehicle (BEV) via an electric vehicle charging dispenser that is also provided at the charging station.

A system for electric vehicle charging and hydrogen fueling leverages existing infrastructure of a localized renewable energy microgrid and utilizes excess generated energy to power an electrolyzer to produce hydrogen gas on site that is compressed and stored in a pressure vessel. A first portion of the stored hydrogen gas may be used for hydrogen fueling of a fuel cell electric vehicle (FCEV) via a hydrogen fuel dispenser that is provided at a charging station. A second portion of the stored hydrogen gas may be converted into electricity through use of one or more fuel cells. The generated electricity may be used for charging a battery of a battery electric vehicle (BEV) via an electric vehicle charging dispenser that is also provided at the charging station.

A fluid delivery system or method for the same may include features or steps for dispensing, via a nozzle, a first fluid from a first fluid storage tank of at least two fluid storage tanks. The fluid storage tanks may be separately fluidly coupled to a manifold via respective fluid supply lines. A fluid delivery line fluidly may couple the nozzle to the manifold. A residual first fluid may remain within the delivery line after the dispensing step. The system or method may further include features or steps for connecting the nozzle to a clearance tank. A clearance outlet line may fluidly couple the clearance tank to the manifold. The system or method may further include features or steps for purging the residual first fluid from the fluid delivery line into the clearance tank and delivering the residual first fluid from the clearance tank to the first fluid storage tank.

The subject matter discloses a method, the method comprises receiving an event of capturing a capture of a vehicle; generating a signature of the vehicle from the capture; comparing the signature to a second signature; wherein the second signature is associated with an identified vehicle, the comparing resulting in a level of confidence; and if the level of confidence exceeds a threshold then identifying the vehicle as the identified vehicle.