A method for the flying of a vertical take-off and landing aircraft which uses fixed rotors for both VTOL and forward flight operations. The rotors form a synthetic wing and are positioned to achieve a high span efficiency. The rotors are positioned to even out the lift across the span of the synthetic wing. The synthetic wing may also have narrow front and rear airfoils which may provide structural support as well as providing lift during forward flight, or may have a single center wing. The wing rotors are tilted forward and provide some forward propulsion during horizontal flight.

The present invention relates to the propulsion system and aircraft with vertical take-off and landing—VTOL that uses aerodynamic phenomena of thrust amplification, including at zero speed, to reduce the thrust/weight ratio.

According to the invention, an individual aircraft 1, with vertical take-off and landing, uses a fuselage 2 in the form of a frame 3 that merges two propulsion system, 4 and 5 one in the front and the other in the rear, of the bi-planar type, located at the ends of the fuselage 2. The propulsion system 4 uses two wings 6 and 7, which are superimposed, parallel and distanced by a certain distance D. The rear wing 7 is fixed perpendicularly to the frame 3 in its median area, so that an angle α between 25° and 80° is formed with the horizontal plane in static position. The front wing 6 and the rear wing 7 are secured at their ends by two jet limiters 8. Similarly the rear propulsion system 5 uses two wings 8 and 10. On each rear wing 7 and 10 are installed a number of electric motors 11, preferably located at equal distances from each other. Each electric motor 11 actuates a tractor propeller 12.

A compound helicopter with a fuselage and at least one main rotor that is at least adapted for generating lift in operation, the at least one main rotor being arranged in an upper region of the fuselage, wherein at least one propeller is provided that is at least adapted for generating forward and/or backward thrust in operation. The at least one propeller is mounted to a fixed wing arrangement that is laterally attached to the fuselage, the fixed wing arrangement comprising at least one upper wing and at least one lower wing. An upper wing section arrangement is provided in the upper region of the fuselage, the at least one upper wing of the fixed wing arrangement being mounted to the upper wing section arrangement.

A radial airfoil is an airfoil having a tip profile and a hub profile of an airfoil that were set apart at different angles of attack and joined by lofted top and bottom surfaces. The top surface is usually a convex surface, whereas the bottom surface is a slightly convex to substantially straight flat surface. The lift disc is a device including multiple radial airfoils that generate additional lift from the spent air from a VTOL (Vertical Take-off and Landing) machine, like a drone or helicopter. The lift disc can be used in several ways to assist the VTOL machines to generate lift. It can be used in a static mode where the lift disc is a non-moving element of the VTOL system. In a dynamic mode, the lift disc replaces the propeller and acts as a propeller to generate lift.

A vertical take-off and landing aircraft which uses fixed rotors for both VTOL and forward flight operations. The rotors form a synthetic wing and are positioned to achieve a high span efficiency. The rotors are positioned to even out the lift across the span of the synthetic wing. The synthetic wing may also have narrow front and rear airfoils which may provide structural support as well as providing lift during forward flight. The wing rotors are tilted forward and provide some forward propulsion during horizontal flight.

An aerial vehicle adapted for vertical takeoff and landing using pivoting thrust producing elements for takeoff and landing. An aerial vehicle which is adapted to takeoff with thrust units providing vertical thrust and then transitioning to a horizontal flight path. An aerial vehicle with pivoting thrust units with propellers, wherein some or all of the propellers are able to be stowed and fully nested during forward flight.

A tail sitter aircraft is described, comprising a wing with a closed front section; a fuselage, from which said wing extends; said fuselage extending parallel to a first axis; said wing being a non-planar wing closed in on itself and without free ends; said wing comprising a first portion projecting from said fuselage, a second portion spaced from said first portion; and a first and a second connecting section, which are interposed between respective ends of said first portion and of said second portion, said first portion and said second portion being parallel to one another and extending parallel to a second axis orthogonal to said first axis, said first axis being arranged, in use, vertically in a take-off/landing position and inclined with respect to the vertical direction in a cruising position. Said first and a second connecting section extend parallel to a third axis orthogonal to said second axis and to said first axis, said wing comprising a third portion arranged on the opposite side of said first portion with respect to said second portion and connected to said first portion at their respective ends by first sections extending parallel to said third axis.

A tail sitter aircraft is described that comprises: a fuselage arranged vertically in a take-off/landing position and transversely to a vertical direction in a cruising position of the aircraft; a single wing; at least two first engines configured to exert respective first thrusts directed along respective first axes on the tail sitter; and at least two second engines rotating about respective second axes arranged above said first axes of the first engines, with reference to the cruising position; the at least two second engines being configured to exert respective second thrusts directed along respective second axes on the tail sitter; the first and second engines being carried by the single wing; the single wing comprises a first portion and a second portion mutually staggered from one another; the second portion being arranged above said first portion, with reference to said cruising position; said first portion comprises two half-wings, extending from opposite lateral sides of the fuselage; the wing further comprises a third portion arranged below said first portion with reference to said cruising position of said aircraft.

An aircraft wing device having one or more numbered wing sets, each wing set further comprising: one or more internal wings, one or more external wings and a transition unit. The internal wings are used to structurally connect the wing set with the main aircraft body, and the external wings are capable of being positionally adjusted and maneuvered by way of vertical, horizontal, or angular movement. The device not only reduces the wingspan of the traditionally used aircraft wings, but also provides better stability and reduces the takeoff time. The wing sets may be positionally staggered on the aircraft body, height wise for aerodynamics efficiency and lift efficiency.

An aerial vehicle adapted for vertical takeoff and landing using a set of wing mounted thrust producing elements and a set of tail mounted rotors for takeoff and landing. An aerial vehicle which is adapted to vertical takeoff with the rotors in a rotated, take-off attitude then transitions to a horizontal flight path, with the rotors rotated to a typical horizontal configuration. The aerial vehicle uses different configurations of its wing mounted rotors and propellers to reduce drag in all flight modes.