A drone docking structure of an autonomous vehicle can include: a coil housing having a space for docking a drone to the vehicle; a docking cover configured to open or close a top portion of the coil housing according to whether the drone is docked; and a motor housing installed on a side surface of the coil housing and including a motor configured to actuate the docking cover.

The present invention relates to the field of the unmanned aerial vehicles, in particular to a suspended landing and take-off and management base.

A multicopter landing platform includes a base portion, a bottom portion, disposed in the base portion, that accepts a protruding portion of the multicopter, and walls of the base portion that are sloped toward the bottom portion. The walls of the base portion may form a conic-shape. The multicopter landing platform may also include a GPS device that sends RTK corrections to a different GPS device on the multicopter. The multicopter landing platform may also include a beacon that guides the multicopter to cause the multicopter to contact the walls of the base station. The beacon may be disposed in the bottom portion. The beacon may provide a signal that is detected by the multicopter. The beacon may provide a light signal that is detected by a camera on the multicopter to guide the multicopter toward the base portion. A charging ring may be disposed in the bottom portion.

A modular vertical take-off and landing aircraft for transporting persons and/or loads, comprising a flight module with multiple drive units arranged on a supporting framework structure, each drive unit having an electric motor and a propeller operatively connected to the electric motor, a transport module having a conveying pod and a connection device for connecting the conveying pod to the flight module. The connection device has an elongated shaft, one end of which is attached to the conveying pod, and a coupling device for connecting the flight module to another end of the elongate shaft of the transport module.

Disclosed is a transport module (1) for a vertical take-off and landing aircraft for transporting persons and/or loads, having a conveying pod (2) and a connection device (3) for connecting the conveying pod (2) to a flight: module (5). The connection device (3) has an elongate shaft (6), one end of which has a coupling device (4) and the other end of which is attached to the conveying pod (2).

Disclosed is a take-off and landing station (1) for a flying vehicle (2) for transporting people and/or loads, which flying vehicle takes off and lands vertically and comprises a flight module (3), having a plurality of drive units (17) arranged on a supporting framework structure (16) of the flight module (3), and a transportation module (4), which can be coupled to the flight module (3). The take-off and landing station (1) comprises a holding apparatus (21) having a plurality of gripper elements and support elements (11) for supporting, fixing and/or orienting the supporting framework structure (16) during take-off and landing of the flying vehicle (2) or the flight module (3).

A mooring system including a plurality of connected floats and weights being positively buoyant on a water surface and being negatively buoyant at a depth below the water surface. The mooring system also includes a trigger mechanism arranged to reduce the buoyancy of a portion of the connected floats and weights from a being positively buoyant to negatively buoyant to cause the portion of the connected floats and weights to sink below the water surface where the trigger mechanism changes the buoyance of the portion of the connected floats and weights by either adding a weight to one end or separating the end from a buoyant element.

An unmanned aerial vehicle (UAV) ground station, comprising: a landing surface having a perimeter and a center; a plurality of pushers held above the landing surface by a plurality of linear actuators; at least one electro-mechanical connector attached to one of the plurality of pushers, mechanically adapted to be electrically connected to a compatible electro-mechanical connector of a UAV; and a landing detection controller adapted to instruct the plurality of linear actuators to move the plurality of pushers simultaneously from the perimeter toward the center when a landing event related to the UAV is detected.

A system for securing an aerial vehicle to a lower portion of a docking station, including a docking station having a top section located in an upper portion of the docking station, the top section having an interface configured to hang the docking station above the ground and a bottom section located in a lower portion of the docking station, the docking station having a latching mechanism located on the bottom section, configured to secure the aerial vehicle to the docking station, the system also including the aerial vehicle having a docking member configured to dock the aerial vehicle into the docking station and to release the aerial from the latching mechanism of the docking station, and a processing module configured to control the operation of the docking member.

Provided is a station for an unmanned aerial robot includes a control box having a landing surface formed with a guide mark which guides a landing point of the unmanned aerial robot, an elevator disposed in the control box and movable vertically, and a landing stand coupled to the elevator and have a height of a highest point located at least above the landing surface during vertical movement. The present disclosure can be linked with an artificial intelligence module, a robot, an augmented reality (AR) device, a virtual reality (VR) device, devices related to 5G services and the like.