A biplane flying device includes a fuselage, an upper wing, a lower wing, a first propulsion assembly and a second propulsion assembly. The upper wing is connected to one side of the fuselage. The upper wing has a first end and a second end opposite to each other. The lower wing is connected to the fuselage and opposite to the upper wing. The lower wing has a third end and a fourth end opposite to each other. The first end is opposite to the third end, and the second end is opposite to the fourth end. The first propulsion assembly is connected between the first end, the third end and the fuselage. The second propulsion assembly is connected between the second end, the fourth end and the fuselage.

A propulsion system for an aerial vehicle having a wing structure operating in a wildfire environment, wherein the wing structure includes a drive extending through a top and a bottom surface of the wing structure and configured to provide a thrust through the top and bottom surface of the wing structure along a vertical axis of the aerial vehicle. The drive may be magnetohydrodynamic drive or an open Nacelle Fan assembly. The drive may be magnetohydrodynamic drive or an open Nacelle Fan assembly The Open Nacelle Propulsion Fan uses a drive mechanism with an induced magnetic field generated by an induction coil housed within the fan assembly open to the ambient environment, a counter-rotating fan assembly including a first fan rotating clockwise, and configured to adjust the pitch of the propulsion fan, thereby enabling the aerial vehicle's thrust to be vectored as determined by the command module.

A propulsion system for an aerial vehicle having a wing structure operating in a wildfire environment, wherein the wing structure includes a drive extending through a top and a bottom surface of the wing structure and configured to provide a thrust through the top and bottom surface of the wing structure along a vertical axis of the aerial vehicle. The drive may be magnetohydrodynamic drive or an open Nacelle Fan assembly. The drive may be magnetohydrodynamic drive or an open Nacelle Fan assembly The Open Nacelle Propulsion Fan uses a drive mechanism with an induced magnetic field generated by an induction coil housed within the fan assembly open to the ambient environment, a counter-rotating fan assembly including a first fan rotating clockwise, and configured to adjust the pitch of the propulsion fan, thereby enabling the aerial vehicle's thrust to be vectored as determined by the command module.

An aircraft can include a stacked propeller to generate lift during assent and descent. The stacked propeller includes a first propeller and a second propeller that co-rotate about an axis of rotation. In one embodiment, the blades are coupled to a rotor mast that contains an internal cavity. In one mode of operation, the first propeller and/or the second propeller can be stored in the internal cavity in order to reduce drag during flight. The aircraft can include one or more stacked propellers, such as a port propeller and a starboard propeller, which rotate in opposite directions during one or more modes of flight.

A propulsion device includes a propulsion body and a diversion assembly. The propulsion body includes a propulsion system and a housing accommodating the propulsion system. The housing has an air-intake opening and an air-discharge opening respectively on two opposite sides of the propulsion system. The diversion assembly includes first and second diversion annular sheets. The first diversion annular sheet is disposed outside the air-discharge opening of the housing and having a surrounding center. The first diversion annular sheet is swung relative to the air discharge opening by a first axis passing through the surrounding center. The second diversion annular sheet is disposed outside the air-discharge opening of the housing and concentrically disposed with the first diversion annular sheet. The second diversion annular sheet is swung relative to the air-discharge opening by a second axis passing through the surrounding center, and first axis intersects the second axis.

The present invention relates to an airplane capable of hyper-short/vertical takeoff and landing (hyper-STOL/VTOL) and having non-rotatable vertical propulsions. It attempts to overcome a limitation of QuadPlane design by making efficient use of both horizontal and vertical propulsions during hovering and vertical flight.

A ducted-rotor aircraft may include a fuselage and first and second ducts that are coupled to the fuselage at respective first and second locations. The first location may be on a first side of a fuselage of the aircraft and spaced from a nominal yaw axis of the aircraft. The second location may be on an opposed second side of the fuselage and spaced from the nominal yaw axis. Each duct may include a rotor that is disposed in an opening that extends through the duct. Each rotor may include a plurality of blades. Each duct may further include a control vane that is mounted aft of the plurality of blades and that is pivotable about a vane axis that is oriented toward the nominal yaw axis.

One example includes an aircraft retrofit system to provide a retrofitted aircraft from an original aircraft. The system includes a plurality of multi-axis vectoring nozzles configured to replace a respective plurality of original nozzles of a respective plurality of original engines of the original aircraft and empennage of the original aircraft, such that the retrofitted aircraft includes no empennage. The system also includes retrofit electronics for controlling the plurality of multi-axis vectoring nozzles to provide yaw control of the retrofitted aircraft.

An aircraft for neutralizing flight comprising a fuselage, at least a power source, a plurality of laterally extending elements attached to the fuselage, a plurality of downward directed propulsors attached to the plurality of laterally extending elements and electrically connected to at least a power source, wherein the plurality of downward directed propulsors have a rotational axis offset from a vertical axis by a yaw-torque-cancellation angle, and a flight controller configured to include a notification unit.

An aircraft for neutralizing flight comprising a fuselage, at least a power source, a plurality of laterally extending elements attached to the fuselage, a plurality of downward directed propulsors attached to the plurality of laterally extending elements and electrically connected to at least a power source, wherein the plurality of downward directed propulsors have a rotational axis offset from a vertical axis by a yaw-torque-cancellation angle, and a flight controller configured to include a notification unit.