A truck assembly for aircraft landing gear is provided. The truck assembly includes a hinge connecting a truck beam to a strut of the landing gear. The hinge is configured to allow the truck beam to rotate about the hinge relative to the strut transversely with respect to the length of the truck beam to thereby pivot the truck assembly relative to the strut between a landing position and a stowing position.

A retractable landing gear assembly for an aircraft includes a leg mounted to airframe structure for rotation about a pivot axis. A stay assembly is provided for maintaining the landing gear assembly in a deployed, for example down and unlocked, configuration. The stay assembly has a linkage mechanism including a first stay and a second stay movable between a folded state and an unfolded state. Room that would otherwise be occupied within a landing gear bay may be freed up above the landing gear leg when in a stowed configuration by the stay assembly being unfolded but generally aligned with the length of the landing gear leg, with the stay assembly being mostly positioned beneath the leg.

The emergency landing gear actuator for aircraft utilizes a pair of airbags for rapid emergency deployment of landing gear when the conventional hydraulic actuator fails. In the retracted position, the at least one wheel of the landing gear is stored in a first cavity formed in the lower portion of the wing. The shock strut and the side strut are stored in an adjacent second cavity formed in the lower portion of the wing. First and second airbags are respectively mounted in the first and second cavities. The first airbag and the second airbag are each selectively inflatable for emergency deployment of the at least one wheel, the shock strut and the side strut. When the hydraulic actuator fails to deploy the landing gear, the first and second airbags are inflated, forcing the shock strut to rotate and position the at least one wheel in its deployed position.

The emergency landing gear actuator for aircraft utilizes a pair of airbags for rapid emergency deployment of landing gear when the conventional hydraulic actuator fails. In the retracted position, the at least one wheel of the landing gear is stored in a first cavity formed in the lower portion of the wing. The shock strut and the side strut are stored in an adjacent second cavity formed in the lower portion of the wing. First and second airbags are respectively mounted in the first and second cavities. The first airbag and the second airbag are each selectively inflatable for emergency deployment of the at least one wheel, the shock strut and the side strut. When the hydraulic actuator fails to deploy the landing gear, the first and second airbags are inflated, forcing the shock strut to rotate and position the at least one wheel in its deployed position.

A landing gear includes a fixing mechanism, a driving mechanism disposed on the fixing mechanism, a translating member connected to the driving mechanism and configured to move relative to the fix mechanism whey being driven by the driving mechanism, and two supporting feet disposed opposite to each other. The two supporting feet are pivotally connected to the fixing mechanism and movably connected at two ends of the translating member. The driving mechanism is configured to drive the two supporting feet through the translating member to rotate relative to the fixing mechanism.

A heavy-lift UAV frame includes a central frame portion and a pocket area for receiving an avionics package. Top and bottom plates are secured to the central frame portion and include four corner members that extend diagonally outward therefrom. A plurality of boom hinges are interposed between each of the corner members pivot a boom arm between an extended position for flight and a retracted position for storage and transport. Each boom arm and hinge combination includes a complementary dimension to one side of the central frame portion to position a boom arm parallel thereto when in the retracted position. A plurality of landing gear hinges are positioned along the bottom of the frame and transition a plurality of landing gear legs between a ready for flight position and a storage position. In the storage position each of the legs are positioned diagonally beneath the central frame portion.

A truck assembly for aircraft landing gear is provided. The truck assembly includes a hinge connecting a truck beam to a strut of the landing gear. The hinge is configured to allow the truck beam to rotate about the hinge relative to the strut transversely with respect to the length of the truck beam to thereby pivot the truck assembly relative to the strut between a landing position and a stowing position.

A truck assembly for aircraft landing gear is provided. The truck assembly includes a hinge connecting a truck beam to a strut of the landing gear. The hinge is configured to allow the truck beam to rotate about the hinge relative to the strut transversely with respect to the length of the truck beam to thereby pivot the truck assembly relative to the strut between a landing position and a stowing position.

An energy absorbing landing system for an aircraft having a fuselage includes landing legs rotatably coupled to the fuselage configured to outwardly rotate when receiving a landing load having a magnitude. The energy absorbing landing system also includes an energy absorption unit coupled to the fuselage and cables coupling the energy absorption unit to the landing legs. The energy absorption unit is configured to selectively apply a resistance to the outward rotation of the landing legs via the cables based on the magnitude of the landing load, thereby absorbing the landing load when the aircraft lands.

An aircraft landing gear assembly is disclosed including a landing gear bracket, a fore lever receiving a fore aircraft wheel, an aft lever receiving a rear aircraft wheel, the fore and aft levers being independently moveable, wherein the bracket further comprises a fore lever stop to prevent downwards movement of the fore lever past a lowest rotational position with respect to the bracket at a first angle α.sub.1 forward from the notional bracket axis, and a rear lever stop to prevent downwards movement of the rear lever past a lowest rotational position at a second angle α.sub.2 behind from the notional bracket axis, wherein the first angle is greater than the second angle. An aircraft and a method of landing an aircraft are also disclosed.