초록 ▼

The Longitudinal Flying Wing aircraft idea provides for design of large cargo and passenger aircraft in range from low to high subsonic and transonic speed. Such aircraft would have up to twice lower fuel consumption per unit of payload, higher lift capacity, and a significantly longer range, while

The Longitudinal Flying Wing aircraft idea provides for design of large cargo and passenger aircraft in range from low to high subsonic and transonic speed. Such aircraft would have up to twice lower fuel consumption per unit of payload, higher lift capacity, and a significantly longer range, while having a significantly lower level of noise inside passenger cabin and cockpit relative to classical concept aircraft. This idea is further providing for efficient, reliable, and simple flight controls, hence it may be successfully applied for design of all-size, long range, high-lift-capacity unmanned aircraft throughout the entire range of subsonic speeds.

대표청구항 ▼

We claim: 1. A longitudinal flying wing aircraft having a symmetry plane, said symmetry plane including a longitudinal axis, said longitudinal axis coinciding with airflow direction, said longitudinal flying wing aircraft comprising:a. front and rear airlifting surfaces, said front and rear airlifti

We claim: 1. A longitudinal flying wing aircraft having a symmetry plane, said symmetry plane including a longitudinal axis, said longitudinal axis coinciding with airflow direction, said longitudinal flying wing aircraft comprising:a. front and rear airlifting surfaces, said front and rear airlifting surfaces being set in free airflow, said front and rear airlifting surfaces being mutually arranged along said longitudinal axis, said front and rear airlifting surfaces providing for the aerodynamic lift of said longitudinal flying wing aircraft, said rear airlifting surfaces being arranged behind the gravity center of said longitudinal flying wing aircraft, thus increasing the natural longitudinal dynamic stability of said longitudinal flying wing aircraft with a predetermined size and shape of said front and rear airlifting surfaces,b. means for thrust production, said means for thrust production including a plurality of aircraft engines, said aircraft engines having aerodynamic covers, said aerodynamic covers with said aircraft engines being set in free airflow behind said gravity center, the free lateral ends of said aerodynamic covers being aerodynamically and structurally integrated with said rear airlifting surfaces into a rigid rear integral aerodynamic body in order to prevent the airflow slip around said free lateral ends, hence increasing the aerodynamic reflection of said aerodynamic covers for natural longitudinal dynamic stabilization, thus said aerodynamic covers additionally increasing said natural longitudinal dynamic stability of said longitudinal flying wing aircraft,c. connecting means, said connecting means joining together said front airlifting surfaces and said rigid rear integral aerodynamic body, thus forming a rigid body of said longitudinal flying wing aircraft, said connecting means being shifted along said front airlifting surfaces behind said gravity center to the outermost aft position thereof, said connecting means being shaped as aerodynamic surfaces by airfoils in airflow direction, said aerodynamic surfaces of said connecting means having a sweepback angle, said aerodynamic surfaces of said connecting means being tilted from said symmetry plane in order to result with the increased horizontal projection thereof, said outermost aft position behind said gravity center, said sweepback angle, and said increased horizontal projection of said aerodynamic surfaces of said connecting means providing for the increased contribution of said connecting means to said natural longitudinal dynamic stability, whereas said outermost aft position behind said gravity center and said sweepback angle of said connecting means providing for the highest possible contribution of said rigid rear integral aerodynamic body to said natural longitudinal dynamic stability with said predetermined size and shape of said front and rear airlifting surfaces,