HYBRID ROTORCRAFT HAVING AT LEAST ONE PUSHER OR PULLER PROPELLER, AND AN ASSOCIATED PILOTING METHOD

Abstract

A rotorcraft including a first power plant, at least one main rotor participating at least in providing lift for the rotorcraft in the air, and at least one tail rotor carried by a tail boom, the first power plant including at least one engine. In accordance with the invention, the rotorcraft includes: at least one pusher or puller propeller independent from the at least one main rotor, the at least one pusher or puller propeller participating at least in providing propulsion or traction for the rotorcraft; a second power plant including at least one electric motor; and at least one control member configured to generate a control setpoint or instruction for controlling the at least one electric motor.

Claims

1. A rotorcraft including a first power plant, at least one main rotor participating at least in providing lift for the rotorcraft in the air, and at least one tail rotor carried by a tail boom of the rotorcraft, the first power plant including at least one combustion engine, at least one outlet shaft of the combustion engine, and at least one power transmission main gearbox connected to the outlet shaft as arranged to transmit a first drive torque to the at least one main rotor and to the at least one tail rotor; wherein the rotorcraft further includes: at least one pusher or puller propeller independent from the at least one main rotor, the at least one pusher or puller propeller participating at least in providing propulsion or traction for the rotorcraft; a second power plant including at least one electric motor transmitting a second drive torque to the at least one pusher or puller propeller; and at least one control member configured to generate a control setpoint or instruction for controlling the at least one electric motor.

2. The rotorcraft according to claim 1, wherein the at least one pusher or puller propeller and the power plant are carried by the tail boom and are arranged at a tail stabilizer unit.

3. The rotorcraft according to claim 2, wherein the rotorcraft includes at least one wing arranged below the at least one main rotor going down along an elevation direction Z parallel to an axis of rotation of the at least one main rotor.

4. The rotorcraft according to claim 1, wherein the at least one pusher or puller propeller and the second power plant are carried by a wing arranged below the at least one main rotor going down along an elevation direction Z parallel to an axis of rotation of the at least one main rotor.

5. The rotorcraft according to claim 4, wherein the wing comprises a left half-wing and a right half-wing arranged respectively on a left side and on a right side of an anteroposterior plane of the rotorcraft, the anteroposterior plane being defined by a midplane extending vertically and between a front region and a rear region of the rotorcraft.

6. The rotorcraft according to claim 5, wherein the at least one pusher or puller propeller comprises at least two pusher or puller propellers belonging to a first group, the first group being carried by the left half-wing, and the at least one pusher or puller propeller further comprising at least two pusher or puller propellers belonging to a second group, the second group being carried by the right half-wing.

7. The rotorcraft according to claim 6, wherein the first group of at least two pusher or puller propellers and the second group of at least two other pusher or puller propellers each have the same number N of pusher or puller propellers.

8. The rotorcraft according to claim 7, wherein the first group of at least two pusher or puller propellers and the second group of at least two other pusher or puller propellers are arranged symmetrically about the anteroposterior plane of the rotorcraft.

9. The rotorcraft according to claim 1, wherein the at least one combustion engine is chosen from the group comprising piston engines, rotary engines, and turbine engines.

10. A piloting method for piloting the rotorcraft according to claim 1, wherein, in a normal operating mode, the piloting method includes at least one normal control step for controlling the at least one tail rotor so as to generate at least a third torque on a carrier structure of the rotorcraft, and, in an emergency operating mode, the piloting method includes at least one emergency control step for controlling the at least one pusher or puller propeller so as to generate the third torque on the carrier structure of the rotorcraft.

11. The piloting method according to claim 10, wherein, in the emergency operating mode, the third torque is generated by causing a left thrust from at least one left pusher or puller propeller to vary relative to a right thrust from at least one right pusher or puller propeller, the at least one left pusher or puller propeller and the at least one right pusher or puller propeller being arranged respectively on a left side and on a right side of an anteroposterior plane of the rotorcraft, the anteroposterior plane being defined by a midplane extending vertically and between a front region and a rear region of the rotorcraft.

Description

BRIEF DESCRIPTION OF THE DRAWINGS

[0058] The invention and its advantages appear in greater detail from the following description of examples given by way of illustration with reference to the accompanying figures, in which:

[0059] FIG. 1 is a plan view of a first example of a rotorcraft of the invention;

[0060] FIG. 2 is a plan view of a second example of a rotorcraft of the invention;

[0061] FIG. 3 is a plan view of a third example of a rotorcraft of the invention; and

[0062] FIG. 4 is a block diagram showing a piloting method of the invention.

DETAILED DESCRIPTION OF THE INVENTION

[0063] Elements present in more than one of the figures are given the same references in each of them.

[0064] Three mutually orthogonal directions X, Y, and Z are shown in each of the FIGS. 1 to 3.

[0065] The first direction X is said to be “longitudinal”. The term “longitudinal” relates to any direction parallel to the first direction X.

[0066] The second direction Y is said to be “transverse”. The term “transverse” relates to any direction parallel to the second direction Y.

[0067] Finally, the third direction Z is said to be “in elevation”. The term “in elevation” relates to any direction parallel to the third direction Z.

[0068] As shown in FIG. 1, the invention thus relates to a rotorcraft 1 including a first power plant 2 mounted on a carrier structure 19, at least one main rotor 3 that participates at least in providing lift for the rotorcraft 1 in the air, and at least one tail rotor 4 that is carried by a tail boom 5 and that makes it possible, in particular, to control the movement of the rotorcraft 1 about its yaw axis.

[0069] In addition, the first power plant 2 shown includes at least one combustion engine 6 and makes it possible to transmit a first drive torque to the main rotor 3 and to the tail rotor 4. Such a combustion engine 6 may be chosen, for example, from the group comprising piston engines, rotary engines, and turbine engines.

[0070] Regardless of the embodiment, the first power plant 2 may further include at least one outlet shaft of the combustion engine 6 and at least one power transmission main gearbox connected to said outlet shaft. In addition, such a rotorcraft 1 includes a pusher or puller propeller 7 that is independent from the main rotor 3. Such a pusher or puller propeller 7 then participates in providing propulsion or traction for the rotorcraft 1.

[0071] Furthermore, the rotorcraft 1 includes a second power plant 8 including at least one electric motor 9 that transmits a second drive torque to the pusher or puller propeller 7.

[0072] In a first example of a rotorcraft 1, such a pusher or puller propeller 7 is carried by the tail boom 5 and is arranged at a tail stabilizer unit 15.

[0073] The second power plant 8 is also carried by the tail boom 5 and is arranged at the tail stabilizer unit 15.

[0074] In addition, the rotorcraft 1 includes at least one control member 10 that is configured to generate a control setpoint or instruction for controlling the electric motor(s) 9. Such a control member 10 is then connected via a wired or wireless connection to a control computer (not shown) that receives control setpoints or instructions generated by a human pilot or an autopilot of the rotorcraft by means of the control member 10. The control computer then generates a piece of control information. This piece of control information is then transmitted to the second power plant 8 to generate the second drive torque that is transmitted to the pusher or puller propeller 7.

[0075] As shown in FIG. 2, in a second example of a rotorcraft 11, the carrier structure 19 may also have a wing 12 that extends below the main rotor 3.

[0076] In addition, such a wing 12 may extend symmetrically about an anteroposterior plane. This wing 12 may also comprise a left half-wing 13 arranged on a left side of the anteroposterior plane and a right half-wing 14 arranged on a right side of the anteroposterior plane.

[0077] Advantageously, such a wing 12 may be removable and be mounted or not mounted on the carrier structure 19 depending on the mission to be flown. Similarly, the pusher or puller propeller 7 and the second power plant 8 may also be arranged in removable manner relative to the tail stabilizer unit 15 of the rotorcraft 11.

[0078] Furthermore, in a third example of a rotorcraft 21 that is shown in FIG. 3, at least two pusher or puller propellers 27, 28 and second power plants 17, 18 may be carried by a wing 22 arranged below the main rotor 3 going down along the elevation direction Z parallel to the axis of rotation 16 of the main rotor 3.

[0079] Naturally, in another example of a rotorcraft (not shown), a wing may also have a single pusher or puller propeller. Such a wing may then be in the form of a left half-wing and of a right half-wing. The pusher or puller propeller is then arranged on a right or left one of the half-wings, and the left or right other half-wing then has no pusher or puller propeller.

[0080] In yet another example of a rotorcraft (not shown), a wing may also have two pusher or puller propellers. Such a wing may also be in the form of a left half-wing and of a right half-wing. A left pusher or puller propeller is then arranged on a left half-wing and a right pusher or puller propeller is then arranged on a right half-wing.

[0081] As shown in FIG. 3, such a wing 22 has a left half-wing 23 and a right half-wing 24 arranged respectively on a left side 33 and on a right side 34 of an anteroposterior plane 25 of the rotorcraft 21. Such an anteroposterior plane 25 may be defined as being a midplane extending vertically and between a front region 26 and a rear region 27 of the rotorcraft 21 along the longitudinal direction X.

[0082] Furthermore, such a rotorcraft 21 may include firstly a first group 37 of at least two pusher or puller propellers 27, which first group 37 is carried by the left half-wing 23, and secondly a second group 38 of at least two other pusher or puller propellers 28, which second group 38 is carried by the right half-wing 24.

[0083] As shown in this third example of a rotorcraft 21, the first group 37 comprises two pusher or puller propellers 27 and the second group 38 comprises two other pusher or puller propellers 28. In other examples of rotorcraft (not shown), the first and second groups 37 and 38 may also comprise three or four pusher or puller propellers 27 and 28 each.

[0084] Furthermore, the first group 37 and the second group 38 may advantageously be arranged symmetrically about the anteroposterior plane 25 of the rotorcraft 21.

[0085] As shown in FIG. 4, the invention also relates to a piloting method for piloting such a rotorcraft 1, 11, 21. Such a method 40 has two operating modes, namely a normal operating mode 42 and, if a failure occurs at the tail rotor 4, an emergency or contingency operating mode 44.

[0086] In the normal operating mode 42, the piloting method 40 includes a normal control step 41 for controlling the tail rotor 4 in such a manner as to generate at least a third torque on the carrier structure 19 of the rotorcraft 1, 11, 21, and as to make it possible to control the movements of the rotorcraft 1, 11, 21 about a yaw axis.

[0087] Conversely, when a failure is detected at the tail rotor 4, then the piloting method 40 goes over to the emergency operating mode 44.

[0088] In this situation, the piloting method 40 then includes at least one emergency control step 43 for controlling the pusher or puller propeller(s) 7, 27, 28 in such a manner as to generate the third torque on said carrier structure 19 of the rotorcraft 1, 11, 21.

[0089] Thus, in the emergency operating mode only, the pusher or puller propeller(s) 7, 27, 28 may make it possible to control a yaw path of the rotorcraft 1, 11, 21.

[0090] In the emergency operating mode 44, the third torque may thus be generated by causing a left thrust from at least one left pusher or puller propeller 27 to vary relative to a right thrust from at least one right pusher or puller propeller 28.

[0091] Conversely, the third torque may also be generated by causing the right thrust from at least one right pusher or puller propeller 28 to vary relative to the left thrust from at least one left pusher or puller propeller 27.

[0092] Naturally, the present invention may be subjected to numerous variations as to its implementation. Although several embodiments and implementations are described above, it should readily be understood that it is not conceivable to identify exhaustively all possible embodiments and implementations. It is naturally possible to envisage replacing any of the means described by equivalent means without going beyond the ambit of the present invention.