IPC분류정보
국가/구분 |
United States(US) Patent
등록
|
국제특허분류(IPC7판) |
|
출원번호 |
US-0161693
(2008-04-25)
|
등록번호 |
US-8113460
(2012-02-14)
|
우선권정보 |
FR-07 03614 (2007-05-22) |
국제출원번호 |
PCT/FR2008/000604
(2008-04-25)
|
§371/§102 date |
20080722
(20080722)
|
국제공개번호 |
WO2008/145868
(2008-12-04)
|
발명자
/ 주소 |
|
출원인 / 주소 |
|
대리인 / 주소 |
|
인용정보 |
피인용 횟수 :
7 인용 특허 :
9 |
초록
▼
A hybrid helicopter (1) includes firstly an airframe provided with a fuselage (2) and a lift-producing surface (3), together with stabilizer surfaces (30, 35, 40), and secondly with a drive system including: a mechanical interconnection system (15) between firstly a rotor (10) of radius (R) with col
A hybrid helicopter (1) includes firstly an airframe provided with a fuselage (2) and a lift-producing surface (3), together with stabilizer surfaces (30, 35, 40), and secondly with a drive system including: a mechanical interconnection system (15) between firstly a rotor (10) of radius (R) with collective pitch and cyclic pitch control of the blades (11) of the rotor (10), and secondly at least one propeller (6) with collective pitch control of the blades of the propeller (6); andat least one turbine engine (5) driving the mechanical interconnection system (15). The speed of rotation (Ω) of the rotor (10) is equal to a first speed of rotation (Ω1) up to a first flightpath air speed (V1) of the hybrid helicopter (1), and is then reduced progressively in application of a linear relationship as a function of the flightpath air speed of the hybrid helicopter.
대표청구항
▼
1. A hybrid helicopter having a long range and a high forward speed, the helicopter comprising: an airframe made up of: a fuselage;a lift-producing surface secured to the fuselage; andstabilizing and maneuvering surfaces, namely for pitch: a horizontal stabilizer with at least one pitch control surf
1. A hybrid helicopter having a long range and a high forward speed, the helicopter comprising: an airframe made up of: a fuselage;a lift-producing surface secured to the fuselage; andstabilizing and maneuvering surfaces, namely for pitch: a horizontal stabilizer with at least one pitch control surface that is movable relative to the front portion; and for steering: at least one suitable stabilizer; andan integrated drive system constituted by: a mechanical interconnection system between firstly a rotor of radius (R) with collective pitch and cyclic pitch control of the blades of said rotor, and secondly at least one propeller with collective pitch control of the blades of said propeller; andat least one turbine engine driving the mechanical interconnection system;wherein said rotor is continuously driven in rotation by said at least one turbine engine regardless of the stage of flight in a normal configuration of said hybrid helicopter such that the rotational speed of the rotor varies in relation to the rotational speed of the at least one turbine, and the speed of rotation (Ω) of the rotor is equal to a first speed of rotation (Ω1) up to a first flightpath air speed (V1) of said hybrid helicopter, and is then reduced progressively in application of a linear relationship as a function of the flightpath air speed of said hybrid helicopter. 2. A hybrid helicopter according to claim 1, wherein the slope of said linear relationship is equal to (−1/R) in a coordinate system in which the flightpath air sped (V) of the hybrid helicopter is plotted along the abscissa and the speed of rotation (Ω) of the rotor is plotted up the ordinate. 3. A hybrid helicopter according to claim 1, wherein starting from the first speed of rotation (Ω1), the speed of rotation (Ω) of the rotor is reduced progressively to a second speed of rotation (Ω2) at a second flightpath air speed (V2) of the hybrid helicopter. 4. A hybrid helicopter according to claim 1, wherein the slope of said linear relationship is equal to (−1/R) in a coordinate system in which the flightpath air sped (V) of the hybrid helicopter is plotted along the abscissa and the speed of rotation (Ω) of the rotor is plotted up the ordinate, wherein starting from the first speed of rotation (Ω1), the speed of rotation (Ω) of the rotor is reduced progressively to a second speed of rotation (Ω2) at a second flightpath air speed (V2) of the hybrid helicopter, and wherein the first speed of rotation (Ω1) of the rotor is about 260 rpm. 5. A hybrid helicopter according to claim 4, wherein the first speed of rotation (Ω1) of the rotor (10) is substantially equal to 263 rpm, the diameter of the rotor being substantially equal to 16 m. 6. A hybrid helicopter according to claim 1, wherein the slope of said linear relationship is equal to (−1/R) in a coordinate system in which the flightpath air sped (V) of the hybrid helicopter is plotted along the abscissa and the speed of rotation (Ω) of the rotor is plotted up the ordinate, wherein starting from the first speed of rotation (Ω1), the speed of rotation (Ω) of the rotor is reduced progressively to a second speed of rotation (Ω2) at a second flightpath air speed (V2) of the hybrid helicopter, wherein the first speed of rotation (Ω1) of the rotor is about 260 rpm, wherein the first speed of rotation (Ω1) of the rotor is substantially equal to 263 rpm, the diameter of the rotor being substantially equal to 16 m, and wherein the first flightpath air speed (V1) is substantially equal to 125 kt. 7. A hybrid helicopter according to claim 3, wherein second speed of rotation (Ω2) of the rotor is substantially equal to 205 rpm. 8. A hybrid helicopter according to claim 3, wherein the second flightpath air speed (V2) is substantially equal to 220 kt. 9. A hybrid helicopter according to claim 1, wherein the Mach number at the ends of advancing blades is less than 0.85 up to the first flightpath air speed (V1), and is maintained constant and equal to 0.85 between the first and second flightpath air speeds. 10. A hybrid helicopter according to claim 1, wherein the lift/drag ratio (F) of the wing and the rotor taken together is greater than 12 for a flightpath air speed greater than 150 kt. 11. A hybrid helicopter according to claim 1, wherein the output speeds of rotation of said at least one turbine engine , of said at least one propeller, of the rotor, and of the mechanical interconnection system are mutually proportional, the proportionality ratio being constant whatever the flight configuration of the hybrid helicopter under normal operating conditions of the integrated drive system. 12. A hybrid helicopter according to claim 11, wherein said rotor provides firstly all of the lift needed for takeoff, landing, hovering, and vertical flight, and secondly always a portion of the lift needed for cruising flight, said rotor always being driven in rotation by said at least one turbine engine, with this being done without contribution either to traction or to drag. 13. A hybrid helicopter according to claim 11, wherein said rotor provides firstly all of the lift needed for takeoff, landing, hovering, and vertical flight, and secondly always a portion of the lift needed for cruising flight, said rotor always being driven in rotation by said at least one turbine engine, with this being done with little contribution to traction, and no contribution to drag. 14. A hybrid helicopter according to claim 12, wherein the lift developed by the rotor is about 1.05 times the weight of the hybrid helicopter for a flightpath air speed of zero, and 0.69 times said helicopter weight for a flightpath air speed greater than 220 kt, intermediate values being equal to: 0.98 at 50 kt; 0.96 at 80 kt; 0.90 at 125 kt; 0.85 at 150 kt; 0.81 at 170 kt; and 0.74 at 200 kt. 15. A hybrid helicopter according to claim 1, wherein the horizontal stabilizer and the vertical stabilizer form a one-piece assembly of upside-down U-shape towards the fuselage. 16. A hybrid helicopter according to claim 1, wherein two turbine engines are disposed on the fuselage. 17. A hybrid helicopter according to claim 1, wherein the at least one turbine engine includes two turbine engines disposed on the wing, each turbine engine being on a respective side of said fuselage. 18. A hybrid helicopter according to claim 1, wherein the antitorque function is provided by a single propeller. 19. A hybrid helicopter according to claim 1, wherein the at least one propeller is two propellers; and wherein the antitorque function is provided by differential thrust between the two propellers, one delivering thrust towards the front and the other thrust towards the rear of the hybrid helicopter. 20. A hybrid helicopter according to claim 1, wherein the at least one propeller is two propellers, each positioned on opposing sides of the fuselage and configured to provide thrust to propel the hybrid helicopter.
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