A robotic system for fueling or charging a vehicle having a vehicle connector, the robotic system including a robotic arm having a plurality of sequentially arranged articulated links and at least one group of operating cables extending from a proximal end of the arm to terminate at a control link, for controlling the position of that link, the cables each having a path comprising a passage in each successive more proximal link for closely receiving the cable, a flexible conduit operably connected with the robotic arm for delivering a fluid or an electrical current, respectively, to a vehicle, the conduit being connected to a source at a first end and a delivery connector at a second end, and a control system for operating the robotic arm and the hose or cable, wherein the control system directs the robotic arm to engage the vehicle connector with the delivery connector and, upon engagement of the vehicle connector and delivery connector, the control system relaxes the robotic arm to an under-constrained condition.

A robotic servicing system. The robotic servicing system includes an evacuation system, a refill system and a robotic assembly. The evacuation system includes a first quick connect fitting configured to mate with a quick connect valve of a vehicle. The refill system includes a second quick connect fitting configure to mate with the quick connect valve of the vehicle. The robotic assembly is couplable to the evacuation system and the refill system, and is configured to autonomously connect the first and second quick connection fittings to the quick connect valve of the vehicle.

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.

A robotic servicing system. The robotic servicing system includes an evacuation system, a refill system and a robotic assembly. The evacuation system includes a first quick connect fitting configured to mate with a quick connect valve of a vehicle. The refill system includes a second quick connect fitting configure to mate with the quick connect valve of the vehicle. The robotic assembly is couplable to the evacuation system and the refill system, and is configured to autonomously connect the first and second quick connection fittings to the quick connect valve of the vehicle.

An automated fueling assembly includes a refueling station that is positioned at a gas station for refueling gas burning vehicles. The refueling station includes a control panel that is movably integrated into the refueling station to facilitate a driver of a vehicle to access the control panel. The refueling station includes a robotic arm that is actuatable to extend into a refueling port in the vehicle for refueling the vehicle without requiring the driver to exit the vehicle. A pair of sensing units is each positioned on a driveway adjacent to the refueling station. Furthermore, the refueling station is turned on when each the sensing units senses the weight of the vehicle.

A system and a method for mobilized autonomous hydrogen refueling of vertical lift aircraft using a framed landing pad with sensors, an onboard hydrogen storage tank, an onboard refueling arm configured to couple the hydrogen storage tank to the aircraft and an onboard controller configured to control a flow of fuel from the hydrogen storage tank to the aircraft.

An autonomous fueling system to dispense fuel to a vehicle. The system may include a fuel dispenser configured to autonomously deliver fuel to a vehicle. A server may monitor the fueling event. The system may also include a user device configured to communicate with the fuel dispenser and/or the server to order the fuel. The dispenser may be configured to autonomously insert a nozzle into the fuel system of the vehicle and deliver the fuel.

A robotic system for fueling or charging a vehicle having a vehicle connector, the robotic system including a robotic arm having a plurality of sequentially arranged articulated links and at least one group of operating cables extending from a proximal end of the arm to terminate at a control link, for controlling the position of that link, the cables each having a path comprising a passage in each successive more proximal link for closely receiving the cable, a flexible conduit operably connected with the robotic arm for delivering a fluid or an electrical current, respectively, to a vehicle, the conduit being connected to a source at a first end and a delivery connector at a second end, and a control system for operating the robotic arm and the hose or cable, wherein the control system directs the robotic arm to engage the vehicle connector with the delivery connector and, upon engagement of the vehicle connector and delivery connector, the control system relaxes the robotic arm to an under-constrained condition.

A robotic servicing system. The robotic servicing system includes an evacuation system, a refill system and a robotic assembly. The evacuation system includes a first quick connect fitting configured to mate with a quick connect valve of a vehicle. The refill system includes a second quick connect fitting configure to mate with the quick connect valve of the vehicle. The robotic assembly is couplable to the evacuation system and the refill system, and is configured to autonomously connect the first and second quick connection fittings to the quick connect valve of the vehicle.

An automatic fuel dispensing system is provided. The automatic fuel dispensing system includes an electronic terminal and a robotic arm. The electronic terminal houses a processor. The robotic arm is also controlled by the processor. The processor is programmed to perform a fueling program that will result in the refueling of an automobile. The fueling program provides a number of fuel options from which the user can select. When a fuel option is selected, a payment process is undergone, during which the customer pays for the refueling. Once the payment process is enacted, the fueling process is conducted. The fueling process causes the robotic arm to fuel the automobile.