A method for designing and operating aircraft nose landing gear wheel-mounted electric taxi systems to move aircraft during ground travel. Electric taxi system components are engineered and sized to produce optimal ground travel torque to move aircraft during the majority of aircraft ground travel and are operated in conjunction with the aircraft steering to turn the nose wheels to an effective angle that moves the aircraft during pushback and in breakaway situations. The nose landing gear wheels are turned to an effective angle and the electric taxi systems are operated simultaneously to get the aircraft moving. After breaking away, the aircraft is driven with electric taxi systems at the optimal ground travel torque in a forward or reverse direction with the nose wheels parallel or in a desired ground travel direction with the nose wheels steered in the desired direction of ground travel.

An aircraft undercarriage including a wheel, a support, a drive system, a mover system, a first pair of links, and a locking actuator. The drive system drives rotation of the wheel and is mounted to move relative to the support between an engaged position and a disengaged position. The mover system moves the drive system between the engaged and disengaged positions. The first pair of links are hinged to each other about a first hinge axis to pivot during the movement of the drive system between the engaged and disengaged positions. The locking actuator acts on a first target to lock or unlock the drive system. The first target is carried by one of the links.

Aircraft landing gears include at least one wheel, an electric taxiing system including an electric taxiing motor, brakes capable of slowing down or stopping the rotation of the wheel, and a cooling system for cooling the electric taxiing motor and the brakes. The cooling system includes ventilation means capable of mixing a first air flow originating from the brakes and a second air flow originating from outside the landing gear and of ventilating the electric taxiing motor with a mixture of the two air flows.

An aircraft landing gear includes a strut leg, a bottom portion carrying at least one wheel and mounted to slide in the strut leg, and a plurality of elements such as power electric cables, signal-carrying electric cables, and hydraulic pipes extending toward the bottom portion along the strut leg and terminating at the bottom portion, all of the elements being flexible between a bottom end of the strut leg and the bottom portion of the landing gear. The landing gear includes a first movable support having a proximal end hinged to the bottom end of the strut leg, and a distal end carrying a rack for receiving and guiding the flexible elements. The landing gear also includes a second movable support having a distal end hinged to the bottom portion of the landing gear and a proximal end carrying a rack for receiving and guiding the flexible elements.

A method for engaging a first gear element with a second gear element is provided. The second gear element is mounted to be mobile between a meshing position and a position of disengagement using an actuator. The method includes driving one or more of the first and second gear elements in rotation to form a non-zero rotation speed difference between the first and second gear elements and controlling the actuator to successively displace the second gear element to the meshing position, and when an intermediate position of the second gear element is detected, stop the displacement of the second gear element, and when an angular position of engagement of the first and second gear elements is detected, displace the second gear element to the meshing position.

An integrated pushback guidance system and method is provided for guiding pushback travel of electric taxi system-driven aircraft. The pushback guidance system may be integrated with existing ramp monitoring systems to monitor reverse pushback travel of pilot-controlled electric taxi system-driven aircraft along an optimum pushback path from a stand to a pushback end location. Visual signals relating to pushback travel safety as the pilot drives the aircraft along the pushback path are generated in real time by the system and transmitted to a range of display devices viewable by the aircraft pilot and airport personnel responsible for guiding aircraft pushback. The pilot may be guided by visual signals on only display devices or with guidance from airport personnel also viewing the visual signals on display devices to drive the aircraft safely in reverse with the electric taxi system along the pushback path to the pushback end location.

A UAV and its power system, and a system for minimizing UAV failure. The UAV power system has a propulsion propeller, which is arranged at the rear end of the UAV; the traction propeller which is arranged at the front end of the UAV; either the traction propeller or the propulsion propeller is the main propeller while the other is the backup one; when the UAV is in the level flight stage, at least one of the traction propeller and the propulsion propeller is in the working state; and the driving component which is used to drive the propulsion propeller and the traction propeller. The UAV power system provided by the disclosure is provided with a traction propeller and a propulsion propeller, respectively, to improve the failure redundancy and reduce the safety deficiency of the probability of common mode failure (CMF).

A ground power system for supplying electrical power to an aircraft and method of using the same is disclosed in which an electric motor is connected to an aircraft wheel to drive the aircraft wheel, an autonomous vehicle battery carrier is releasably connected to the aircraft through an articulating robotic arm to power the electric motor and to move the aircraft on the ground to support aircraft taxiing and preparation for takeoff using the battery power from the autonomous vehicle, and a command system releases the autonomous vehicle battery carrier as roll begins but before the aircraft rotates.

A landing gear system includes a wheel rotatably coupled to an axle about an axis. A torque tube is rotatably mounted to the axle about the axis such that the axle extends through a central portion of the torque tube. A rotor is fixed in rotation about the axis relative to the wheel, and a stator is fixed in rotation about the axis relative to the torque tube. The landing gear assembly further includes a clutch assembly selectively reciprocal between an engaged state and a disengaged state. The stator is fixed in rotation about the axis relative to the torque tube when the clutch assembly is in an engaged state. When the clutch assembly is in a disengaged state, the stator is rotatably about the axis relative to the torque tube.

A landing gear system includes a wheel rotatably coupled to the axle about an axis. A motor is fixedly positioned relative to the axle with a clutch assembly operably coupled to an output shaft of the motor. The landing gear includes an actuator and a drive assembly. The actuator applies a braking force to the wheel. The drive assembly includes a pinion gear and a drive gear rotatably associated with the pinion gear. The drive gear is configured to transfer a rotational force to the wheel in order to provide autonomous taxiing capability. Both the brake assembly and the drive assembly are operably coupled to the clutch assembly so that the output shaft of the motor drives both the brake assembly and the drive assembly.