Abstract: Lock apparatus and related methods for use with drones are disclosed. A disclosed drone assembly includes a wing, a keel-beam, an adapter positioned on an end of the keel-beam, and a lock configured to receive the adapter. The lock includes a first lock portion coupled to the wing and a second lock portion rotatable relative to the first lock portion between a first position and a second position. The lock is configured to (a) couple the keel-beam to the wing when the second lock portion is in the second position and (b) decouple the keel-beam from the wing when the second lock portion is in the first position.

Abstract: A network of automated launch and recovery platforms (LRPs) for at least one aircraft-type aerial vehicle (UAV) which automatically perform cyclic tasks of preparation, launch, and recovery without manual operation. Each LRP includes a stationary foundation in an X-Z plane, a rotatable foundation that can rotate around a Y axis of the stationary foundation, and a rotatable leverage that rotates around the Z axis at a shaft driven by a motor. A first leverage of the UAV is hooked to the rotatable leverage of the LRP such that rotation of the shaft by the motor drives the rotatable leverage and the UAV for take-off and reduces UAV to stop during recovery. The network includes a traffic control subsystem and a launch and recovery subsystem which provides initial UAV speed necessary for launch, and ensures dissipation of kinetic energy of a captured UAV during recovery.

Abstract: Lock apparatus and related methods for use with drones are disclosed. A disclosed drone assembly includes a wing, a keel-beam, an adapter positioned on an end of the keel-beam, and a lock configured to receive the adapter. The lock includes a first lock portion coupled to the wing and a second lock portion rotatable relative to the first lock portion between a first position and a second position. The lock is configured to (a) couple the keel-beam to the wing when the second lock portion is in the second position and (b) decouple the keel-beam from the wing when the second lock portion is in the first position.

Abstract: A network of automated launch and recovery platforms (LRPs) for at least one aircraft-type aerial vehicle (UAV) which automatically perform cyclic tasks of preparation, launch, and recovery without manual operation is provided. Each LRP includes a stationary foundation in an X-Z plane, a rotatable foundation that can rotate around a Y axis of the stationary foundation, and a rotatable leverage that rotates around the Z axis at a shaft driven by a motor. A first leverage of the UAV is hooked to the rotatable leverage of the LRP such that rotation of the shaft by the motor drives the rotatable leverage and the UAV for take-off and reduces UAV to stop during recovery. The network includes a traffic control subsystem and a launch and recovery subsystem which provides initial UAV speed necessary for launch, and ensures dissipation of kinetic energy of a captured UAV during recovery.