An aircraft landing gear structure according to the present disclosure includes a strut assembly and a wheel assembly operatively coupled to the strut assembly. The strut assembly includes an upper tubular housing and a lower tubular housing configured to be longitudinally translated with respect to the upper tubular housing such that the overall length of the strut assembly is transitioned between an extended configuration and a retracted configuration for stowage during flight. The wheel assembly includes a forward link pivotally coupled to the upper tubular housing and a truck beam that is pivotally coupled to the lower tubular housing such that translation of the lower tubular housing with respect to the upper tubular housing causes pivoting of the forward link and the truck beam with respect to one another, thereby tilting and/or raising a wheel of the wheel assembly with respect to the upper tubular housing.

An electrically powered STOL aircraft having dedicated motors energized to deploy movable landing gear driven to propel short takeoffs and to actively rotate downwardly to engage the runway surface as the aircraft approaches touchdown on landing. The front and rear landing gear, or both, may be powered and actuated in the landing process with braking to shorten the landing distance, each driven landing gear wheel having a dedicated electric motor and coaxial brake.

An electrically powered STOL aircraft having dedicated motors energized to deploy movable landing gear driven to propel short takeoffs and to actively rotate downwardly to engage the runway surface as the aircraft approaches touchdown on landing. The front and rear landing gear, or both, may be powered and actuated in the landing process with braking to shorten the landing distance, each driven landing gear wheel having a dedicated electric motor and coaxial brake.

The utility model relates to an unmanned aerial vehicle and an undercarriage thereof. The undercarriage includes: a power assembly disposed within a fuselage, the power assembly including a first connecting member and a drive apparatus configured to drive the first connecting member to perform a reciprocating linear motion; and an undercarriage body connected to the power assembly, the undercarriage body including a first connecting rod hinged on the first connecting member, and a second connecting rod of which one end is hinged on the power assembly and the other end is hinged on the first connecting rod. When the first connecting member performs the reciprocating linear motion, the undercarriage body is driven to be unfolded or folded into the fuselage. The utility model further relates to an unmanned aerial vehicle. For the foregoing unmanned aerial vehicle and the undercarriage thereof, the power assembly may be used to drive the undercarriage body to switch between an unfolded state and a folded state. When aerial photography is required, the undercarriage body may be at least partially folded into the fuselage, to avoid blocking an aerial photography device on the unmanned aerial vehicle.

The utility model relates to an unmanned aerial vehicle and an undercarriage thereof. The undercarriage includes: a power assembly disposed within a fuselage, the power assembly including a first connecting member and a drive apparatus configured to drive the first connecting member to perform a reciprocating linear motion; and an undercarriage body connected to the power assembly, the undercarriage body including a first connecting rod hinged on the first connecting member, and a second connecting rod of which one end is hinged on the power assembly and the other end is hinged on the first connecting rod. When the first connecting member performs the reciprocating linear motion, the undercarriage body is driven to be unfolded or folded into the fuselage. The utility model further relates to an unmanned aerial vehicle. For the foregoing unmanned aerial vehicle and the undercarriage thereof, the power assembly may be used to drive the undercarriage body to switch between an unfolded state and a folded state. When aerial photography is required, the undercarriage body may be at least partially folded into the fuselage, to avoid blocking an aerial photography device on the unmanned aerial vehicle.

Embodiments of the present invention relate to the technical field of aircrafts, and provide an undercarriage and an unmanned aerial vehicle (UAV) having the undercarriage. The undercarriage includes a power assembly and an undercarriage body. The power assembly includes a connecting member and a drive apparatus for driving the connecting member to reciprocate. The undercarriage body includes a plurality of hinged connecting rods, the plurality of hinged connecting rods constituting at least one parallelogram mechanism, and projections of at least two of the hinged connecting rods on a side face of the fuselage are staggered. The undercarriage body is connected to the connecting member, and when the connecting member reciprocates, the undercarriage body is driven to be folded or unfolded. In the foregoing manner, driven by the reciprocating motion of the connecting member, the undercarriage body may be retracted and folded on two sides or in an interior of the fuselage, so that the undercarriage may be retracted and folded during flight of the UAV, thereby avoiding unnecessary resistance in the air.

Embodiments of the present invention relate to the technical field of aircrafts, and provide an undercarriage and an unmanned aerial vehicle (UAV) having the undercarriage. The undercarriage includes a power assembly and an undercarriage body. The power assembly includes a connecting member and a drive apparatus for driving the connecting member to reciprocate. The undercarriage body includes a plurality of hinged connecting rods, the plurality of hinged connecting rods constituting at least one parallelogram mechanism, and projections of at least two of the hinged connecting rods on a side face of the fuselage are staggered. The undercarriage body is connected to the connecting member, and when the connecting member reciprocates, the undercarriage body is driven to be folded or unfolded. In the foregoing manner, driven by the reciprocating motion of the connecting member, the undercarriage body may be retracted and folded on two sides or in an interior of the fuselage, so that the undercarriage may be retracted and folded during flight of the UAV, thereby avoiding unnecessary resistance in the air.

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.

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.

An electrically powered STOL aircraft having dedicated motors energized to deploy movable landing gear driven to propel short takeoffs and to actively rotate downwardly to engage the runway surface as the aircraft approaches touchdown on landing. The front and rear landing gear, or both, may be powered and actuated in the landing process with braking to shorten the landing distance, each driven landing gear wheel having a dedicated electric motor and coaxial brake. The landing gear modules are configured and controllable to differentially deploy downwardly so as to enable countersteering during taxi maneuvers and turns.