The present invention provides an aircraft design which incorporates a modular design including the use of one or more multi-motor assemblies where the motors are in series within the multi-motor assembly. Still further, the multi-motor assemblies may be configured to include modular motor assemblies or modular sections. Ultimately, the present invention provides an aircraft with the ability to easily assemble or expand the multi-motor assemblies and, in doing so, modify the characteristics of the aircraft. The modularity also enhances the ability to maintain the aircraft by enabling motors or the units housing each motor to easily be replaced.

A flight module for a vertical take-off and landing aircraft comprises multiple drive units arranged on a supporting framework structure that comprises struts interconnected at node points. Each drive unit comprises an electric motor and a propeller that is operatively connected to the electric motor. Some of the drive units are arranged outside the node points.

Disclosed is a charging station (2) for a vertical take-off and landing aircraft (1) comprising one or more energy stores, the station having a charging device for transferring electrical energy to the energy store or stores. Also disclosed is a combined charging station (12) for vertical take-off and landing aircraft, each aircraft comprising one or more energy stores, the combined charging station (12) having multiple charging stations.

In one possible embodiment, an amphibious unmanned aerial vehicle is provided, which includes a fuselage comprised of a buoyant material. Separators within the fuselage form separate compartments within the fuselage. Mounts associated with the compartments for securing waterproof aircraft components within the fuselage. The compartments each have drainage openings in the fuselage extending from the interior of the fuselage to the exterior of the fuselage.

A modular unmanned aerial vehicle (UAV) system comprises a body module, a rotor module, and a wing module. The body module includes a flight controller and a power distribution device. The body module is releasably attachable to the rotor module or the wing module, and the body module is releasably attachable to the rotor module. The rotor module includes one or more motors and electronic speed controllers (ESCs), while the wing module includes a wing having a flap, elevator, aileron, or rudder. Various UAV configurations can be formed from the body module, the rotor module, and the wing module. Each configuration includes different advantages for flight time, distance, battery life, and payload capacity. A UAV can be configured to a particular configuration to optimize parcel delivery.

A modular unmanned aerial vehicle (UAV) system comprises a body module, a rotor module, and a wing module. The body module includes a flight controller and a power distribution device. The body module is releasably attachable to the rotor module or the wing module, and the body module is releasably attachable to the rotor module. The rotor module includes one or more motors and electronic speed controllers (ESCs), while the wing module includes a wing having a flap, elevator, aileron, or rudder. Various UAV configurations can be formed from the body module, the rotor module, and the wing module. Each configuration includes different advantages for flight time, distance, battery life, and payload capacity. A UAV can be configured to a particular configuration to optimize parcel delivery.

A fixed-wing VTOL hybrid UAV is disclosed comprising: a central frame 104; a pair of quick lockable fixed-wings 102 comprising right wing 102-2 and left wing 102-1 that lock with each other over the central frame; and four electrically operated rotors 108 in downward facing configuration attached to fixed-wings with help of rotor-blade arms 110. Arms 110 are pivotally fixed to wings 102 so that arms 110 are movable between a working position in which arms 110 are oriented parallel to central frame 104, and a storage position in which arms 110 are aligned with wings 102. Central frame 104 is a thin rod and works as fuselage. Drivers and control modules are fitted in wings 102. UAV includes rudders attached to arms at 45 degrees for maneuvering UAV for yaw and a secondary roll response. UAV includes two landing gears 106 attached to each end of central frame.

Disclosed herein is a modular aerial vehicle system having a fuselage module configured to couple with a plurality of lift generation modules. The modular aerial vehicle system may comprise a fuselage module and a lift generation module. The fuselage module can include a first attachment interface, an avionics system operatively coupled with a power unit (e.g., via an ESC), and a communications system operatively coupled with the flight controller. The lift generation module can include a second attachment interface and a plurality of propulsors. The fuselage module may be configured to removably couple with the lift generation module via the first and second attachment interfaces. The first and second attachment interfaces may comprise (1) a plurality of electrical contacts to facilitate electrical communication between the fuselage module and the lift generation module and/or (2) one or more retention devices to couple structurally the lift generation module with said fuselage module.

Systems and methods for pre-flight fabrication and/or assembly of various configurations of aerial vehicles are described. Operations of various configurations of aerial vehicles may be analyzed using models based on various inputs, which inputs may be related to routes, environments, vehicles, components, or other factors. A particular configuration may be selected for a selected route and associated task based at least in part on a desired optimization parameter. Then, the particular configuration of the aerial vehicle may be fabricated and/or assembled to complete the associated task via the selected route.

The present disclosure describes various systems, devices, and methods configured to retrieve a fixed-wing aircraft from free flight using a flexible capture member