초록 ▼

The present invention relates to a method of reducing the vibration of a lift and propulsion rotor (5) of a rotorcraft (1), the rotor having a plurality of airfoil assemblies (10) that perform rotary movement around a drive axis (AX) of the rotor (5), each airfoil assembly (10) comprising a blade (2

The present invention relates to a method of reducing the vibration of a lift and propulsion rotor (5) of a rotorcraft (1), the rotor having a plurality of airfoil assemblies (10) that perform rotary movement around a drive axis (AX) of the rotor (5), each airfoil assembly (10) comprising a blade (20) extending longitudinally from a root (22) suitable for being fastened to hinge means (4) of a hub (6) of said rotor (5) to a free end (21), a first distance (D1) extending between said free end (21) and said hinge means (4). In the method, said first distance (D1) is caused to vary cyclically so that the projection (TR) of the center of gravity (Cg) of a blade (20) on a horizontal plane (P) perpendicular to said drive axis (AX) and containing said hinge means (4) describes a circle.

대표청구항 ▼

1. A method of reducing the vibration of a lift and propulsion rotor of a rotorcraft, the rotor having a plurality of airfoil assemblies that perform rotary movement around a drive axis of the rotor, each airfoil assembly comprising a blade extending longitudinally from a root suitable for being fas

1. A method of reducing the vibration of a lift and propulsion rotor of a rotorcraft, the rotor having a plurality of airfoil assemblies that perform rotary movement around a drive axis of the rotor, each airfoil assembly comprising a blade extending longitudinally from a root suitable for being fastened to hinge means of a hub of said rotor to a free end, a first distance extending between said free end and said hinge means, the method comprising: varying said first distance cyclically so that the projection of the center of gravity of a blade on a horizontal plane perpendicular to said drive axis and containing said hinge means describes a circle. 2. A method according to claim 1, wherein the radius of this circle is equal to 0.5 times the span of the blade between said root and said free end. 3. A method according to claim 1, wherein varying said first distance comprises varying said first distance in proportion to the absolute value of the flapping angle (α) of the blade relative to said horizontal plane. 4. A method according to claim 1, wherein varying said first distance comprises varying the first distance inversely with the cosine of the flapping angle (α) so that the free end of the blade remains at a constant first distance from the drive axis. 5. A method according to claim 1, wherein varying said first distance comprises lengthening said first distance when the blade (20) flaps so that its free end moves away from the horizontal plane. 6. A method according to claim 1, wherein varying said first distance comprises shortening said first distance when the blade flaps to move its free end towards the horizontal plane. 7. An airfoil assembly for a propulsion rotor of an aircraft performing rotary movement about a drive axis, said airfoil assembly being provided with a blade extending from a root towards a free end, said airfoil assembly including a sleeve secured to said root, and wherein said sleeve is provided with a control actuator having first and second fastener means respectively for fastening to hinge means of a hub of a rotor and to said root, said control actuator configured to vary a first distance between said free end and said hinge means during normal flight operation so that the projection of the center of gravity of a blade on a horizontal plane perpendicular to said drive axis containing said hinge means describes a circle. 8. An airfoil assembly according to claim 7, wherein said control actuator is an electric control actuator controlled by a control member, said airfoil assembly being provided with an angle sensor suitable for providing the control member with a signal that is proportional to a flapping angle (α) of the blade relative to a horizontal plane perpendicular to said drive axis and containing said hinge means. 9. An airfoil assembly according to claim 7, wherein said control actuator is a hydraulic control actuator. 10. An airfoil assembly according to claim 9, wherein said hydraulic control actuator comprises a hollow main cylinder provided with said first fastener means and with at least one movable rod passing at least in part through said cylinder, the rod connecting said second fastener means to a separator that slides in a volume of said cylinder so as to define first and second hydraulic control chambers. 11. An airfoil assembly according to claim 10, wherein said cylinder possesses first and second orifices suitable for connecting said first and second hydraulic control chambers respectively to a hydraulic circuit. 12. An airfoil assembly according to claim 10, wherein said airfoil assembly has a hydraulic drive actuator provided with a drive piston with a head that slides in a casing defining first and second drive chambers, said first and second hydraulic control chambers being hydraulically connected respectively to said first and second drive chambers so that an extension of said drive actuator causes said hydraulic control actuator to lengthen and a refraction of said drive actuator causes said hydraulic control actuator to shorten. 13. An airfoil assembly according to claim 12, wherein said drive piston is hinged to a fastener rod fastened to the first fastener means of the sleeve. 14. An airfoil assembly according to claim 13, wherein said fastener rod is arranged along a fastener axis suitable for intersecting said hinge means. 15. A rotor provided with a hub secured to a mast and provided with a plurality of hinge means, each hinge means being fastened to an airfoil assembly, and wherein each airfoil assembly is in accordance with claim 7. 16. A rotor according to claim 15, wherein each airfoil assembly has a hydraulic control actuator having both first fastener means fastened to said hinge means and second fastener means fastened to the root of a blade, said airfoil assembly having a drive actuator that co-operates with said hydraulic control actuator, said drive actuator being fastened to a ball joint that is secured to said mast by a connecting rod. 17. A method of reducing the vibration of a lift and propulsion rotor of a rotorcraft, the rotor having a plurality of airfoil assemblies that rotate about a rotor drive axis, each airfoil assembly comprising a blade extending longitudinally from a blade root to a blade tip to define a blade length, the blade root being configured to couple to a hinge at a rotor hub, the blade having a center of gravity, the method comprising: varying the blade length to maintain a distance between the rotor drive axis and a projection of the blade center of gravity on a horizontal plane perpendicular to the drive axis and passing through the hinge. 18. The method of claim 17, wherein varying the blade length comprises varying the blade length in proportion to the absolute value of a flapping angle (α) of the blade relative to the horizontal plane. 19. The method of claim 17, wherein varying the blade length comprises increasing the blade length when the blade tip moves away from the horizontal plane and decreasing the blade length when the blade tip moves toward the horizontal plane. 20. The method of claim 17, wherein varying the blade length comprises increasing the blade length and decreasing the blade length within a revolution of the blade. 21. The method of claim 17, wherein the projection of the blade center of gravity on the horizontal plane describes a circle.