A system and apparatus for autonomously fueling a surface water vessel such as an unmanned surface vehicles (USV). A fueling system is secured to the dockside of a land secured or waterborne fueling station. The fueling system has a hose reel, a hose pusher and mooring whip for extending the hose out of the water for access to the surface water vessel. The vessel is equipped with an actuated arm that pivots between a closed position and an open position to capture the hose and connect the nozzle of the hose to the fuel tank of the vessel. The fuel tank has an interface with a mounting plate, nozzle interface and electromagnets that pull, positively locate, and hold the nozzle into the nozzle interface to access the fuel tank and to fuel the vessel.

Systems and methods are provided for controlling maintenance of a fuel dispenser. In one exemplary embodiment, a system is provided having a fuel dispenser that includes an electronics module having a data processor, a remote enterprise server in communication with the electronics module, and a remote code processor in communication with the remote enterprise server. The data processor is configured to determine an authorization password based on data characterizing the fuel dispenser, to receive a remote password that is generated by the remote code processor based on the fuel dispenser data, to determine that the remote password matches the authorization password, and to cause the fuel dispenser to enter a maintenance mode.

A fuel storage and supply arrangement serves as a source of fuel to be dispensed via at least one fuel dispenser in a fuel dispensing environment. The arrangement comprises a storage tank for containing a quantity of the fuel. A pump assembly draws the fuel from the storage tank providing the fuel under pressure to a fuel supply line. A fuel conditioning assembly includes a housing having a storage volume, a housing inlet receiving the fuel under pressure created by the pump assembly, a housing outlet through which fuel exits the housing, and a housing port through which fuel can be drawn into the housing. A vacuum source in fluid communication with the housing outlet is operative to selectively apply a vacuum to the outlet of the housing so that liquid can be drawn into the housing via the port. A water intake device is in fluid communication with the housing port. The water intake device has at least one inlet situated adjacent to a bottom of the fuel storage tank.

A breakaway assembly including a first connector and a second connector releasably coupleable to the first connector. The assembly is movable between a first configuration in which the first and second connectors are releasably coupled and together define a fluid path through which fluid is flowable, wherein the fluid path includes an at least partially radially extending portion, and a second configuration in which the first and second connectors are not coupled together. The assembly is configured to move from the first configuration to the second configuration when a predetermined separation force is applied to the assembly. The assembly further includes a closure valve positioned in one of the first or second connectors, wherein the closure valve is configured to be in an open position when the assembly is in the first configuration to allow fluid to flow therethrough, and to move to a closed position blocking the at least partially radially extending portion of the fluid path when the assembly moves to the second configuration to generally block the flow of fluid therethrough.

Aspects and implementations of the present disclosure relate, generally, to optimization of the autonomous vehicle technology and, more specifically, to a transfer hub for autonomous trucking operations. The transfer hub supports automated trailer delivery, trailer-tractor matching, trailer-tractor hitching, automated post-hitching visual inspection, automated refueling, parking spot calibration, load verification, load distribution assessment, automated brake inspection, and other improvements to the existing technology.

Embodiments of systems and methods for transporting fuel and carbon dioxide (CO.sub.2) in a dual-fluid vessel thereby minimizing transportation between locations are disclosed. In an embodiment, the dual-fluid vessel has an outer shell with two or more inner compartments, positioned within the outer shell, including a first inner compartment for storing CO.sub.2 and a second inner compartment for storing fuel. The dual-fluid vessel may connect or attach to a transportation vehicle to thereby allow transportation of the fuel and CO.sub.2. Insulation may provide temperature regulation for the fuel and CO.sub.2 when positioned in the respective first and second inner compartments. One or more ports having an opening in and through the outer shell and a fluid pathway to one or more of the first inner compartment or the second inner compartment may provide fluid communication through the opening and fluid pathway for loading/offloading the fuel and/or CO.sub.2.

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.

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.

Provided is a device for automatic refueling of a vehicle that includes a nozzle having a flexible filler pipe with an open end. The filler pipe is inserted, with the open end first, into the tank pipe to deliver fuel through the open end into the tank pipe. An axial pressure is applied to the filler pipe to insert the filler pipe into the tank pipe. The filler pipe includes an inner fuel pipe of flexible hard plastic material, and an outer metal coil or a series of metal rings. The metal coil or metal rings are arranged to run in parallel to and outside of the inner fuel pipe. The metal coil is arranged to run in and along a recess in the surface of the inner fuel pipe and the metal rings are disposed in a series of annular recesses in the surface of the fuel pipe.

A breakaway assembly including a first connector and a second connector releasably coupleable to the first connector. The assembly is movable between a first configuration in which the first and second connectors are releasably coupled and together define a fluid path through which fluid is flowable, and a second configuration in which the first and second connectors are not coupled together. The assembly is configured to move from the first configuration to the second configuration when a predetermined separation force is applied to the assembly. The assembly includes a closure valve positioned in one of the first or second connectors, wherein the closure valve is configured to be in an open position when the assembly is in the first configuration to allow fluid to flow therethrough, and to move to a closed position when the assembly moves to the second configuration to generally block the flow of fluid therethrough. The assembly includes an attraction member coupled to one of the first or second connectors, and a magnet unit coupled to the other one of the first or second connectors, wherein the attraction member and the magnet unit are magnetically attracted to each other when the assembly is in the first configuration to retain assembly in the first configuration. The magnet unit includes a first portion and a second portion coupled to the first portion that together define a channel therebetween, and the magnet unit further includes a plurality of magnets received in the channel.