초록 ▼

A method of controlling a deflection angle of pitching stabilizer means for an aircraft. The method includes a preliminary stage for preparing at least one control relationship delivering a setpoint angle that is to be reached by the deflection angle as a function of at least one flight parameter of

A method of controlling a deflection angle of pitching stabilizer means for an aircraft. The method includes a preliminary stage for preparing at least one control relationship delivering a setpoint angle that is to be reached by the deflection angle as a function of at least one flight parameter of the aircraft and of an incidence parameter of the pitching stabilizer means. During an operational stage an operational stage (STP2), a “flight” value is determined for each of the flight parameters, a “setpoint” value is determined for the incidence parameter, a setpoint angle is determined by inputting the flight values and setpoint value into the control relationship, and at least one actuator is actuated in order to cause the deflection angle of the pitching stabilizer means to reach the setpoint angle.

대표청구항 ▼

1. A method of controlling a deflection angle of movable pitching stabilizer means of an aircraft, wherein the method comprises: a preliminary stage (STP1) comprising a preparation step (STP1.2) of preparing at least one control relationship providing a setpoint angle that the deflection angle is to

1. A method of controlling a deflection angle of movable pitching stabilizer means of an aircraft, wherein the method comprises: a preliminary stage (STP1) comprising a preparation step (STP1.2) of preparing at least one control relationship providing a setpoint angle that the deflection angle is to reach as a function firstly of at least one flight parameter of the aircraft and secondly of an incidence parameter of the pitching stabilizer means, the incidence parameter being either an aerodynamic angle of incidence of the pitching stabilizer means, or a lift force exerted on the pitching stabilizer means, or a twisting moment measured on a shaft supporting the pitching stabilizer means; andan operational stage (STP2) during which the following steps are performed: determining a “flight” value for each of the flight parameters;determining a “setpoint” value for the incidence parameter;determining a setpoint angle by inputting the flight values and setpoint value into the control relationship; andactivating at least one actuator to cause the deflection angle of the pitching stabilizer means to reach the setpoint angle. 2. A method according to claim 1, wherein the pitching stabilizer means comprise two stabilizer airfoil surfaces arranged laterally on either side of a structure, and a control relationship is established for each stabilizer airfoil surface, with the respective deflection angles of the two stabilizer airfoil surfaces being independent of each other. 3. A method according to claim 1, wherein each flight parameter is selected from a list comprising at least one of the following elements: a longitudinal position parameter (DDM) representing a position of a longitudinal pilot control controlling a longitudinal angle between a lift vector of the aircraft and gravity in a longitudinal plane of the aircraft;a lateral position parameter (DDL) representing a position of a lateral pilot control controlling a lateral angle between the lift vector of the aircraft and gravity in a lateral plane (P2) of the aircraft;a pitching attitude (θ) of the aircraft;a roll attitude (φ) of the aircraft;an air speed (IAS) of the aircraft;a vertical speed (Vz) of the aircraft in the gravity direction; anda power being consumed by a power plant of the aircraft. 4. A method according to claim 1, wherein the preliminary stage (STP1) comprises: a measurement step (STP1.1) during which data is acquired at measurement points associating the values of the flight parameters and the incidence parameter together with the deflection angle of the pitching stabilizer means, each measurement point being obtained by positioning the pitching stabilizer means at a given deflection angle and by measuring in flight the values of the flight parameters and of the incidence parameter; andthe preparation step (STP1.2) during which the control relationship is set up on the basis of the data. 5. A method according to claim 1, wherein the setpoint value is set by an instrument operated by a pilot. 6. A method according to claim 1, wherein the setpoint value is determined automatically using at least one incidence relationship supplying the setpoint value as a function of a stage of flight. 7. A method according to claim 1, wherein the incidence parameter has at least one of the following values: a zero value during a stage of flight performed level at a speed of advance less than a threshold speed;a zero value during a takeoff stage with an aircraft belonging to category A; anda positive value below an incidence threshold during an approach stage of flight for a precision landing. 8. A method according to claim 7, wherein a landing incidence relationship requires an incidence parameter having: a zero value below a first threshold speed of advance (V1);a positive maximum value between a second threshold speed of advance (V2) and a third threshold speed of advance (V3), the second threshold speed of advance (V2) being greater than the first threshold speed of advance (V1), the third threshold speed of advance (V3) being greater than the second threshold speed of advance (V2), the incidence parameter having a value that increases between the first threshold speed of advance (V1) and the second threshold speed of advance (V2); anda negative minimum value beyond a fourth threshold speed of advance (V4), the fourth threshold speed of advance (V4) being greater than the third threshold speed of advance (V3), the incidence parameter having a value that decreases between the third threshold speed of advance (V3) and the fourth threshold speed of advance (V4). 9. A method according to claim 7, wherein a takeoff incidence relationship requires an incidence parameter having: a zero value below a first limit speed of advance; anda negative minimum value beyond a second limit speed of advance, the second limit speed of advance being greater than the first limit speed of advance, the incidence parameter having a value that decreases between the first limit speed of advance and the second limit speed of advance. 10. A method according to claim 7, wherein at least one incidence relationship is modulated by a modulation parameter. 11. A method according to claim 1, wherein during the operational stage (STP2), the setpoint angle is bounded by at least one bound, the bound being: either an upper bound, the setpoint angle begin maintained at the value of the upper bound when the setpoint angle delivered by the control relationship is greater than or equal to the upper bound;or else a lower bound, the setpoint angle being maintained at the value of the lower bound when the setpoint angle delivered by the control relationship is less than or equal to the lower bound. 12. A system for stabilizing an aircraft having pitching stabilizer means, the pitching stabilizer means comprising at least one airfoil surface that is movable in pivoting, the stabilizer system comprising a positioner system for adjusting a deflection angle of the airfoil surface, the positioner system comprising at least one actuator connected to the airfoil surface, wherein the positioner system includes a processor unit acting during the operational stage (STP2) to perform the method according to claim 1, the positioner system including a measurement system for determining each flight value of each flight parameter and a determination system for determining the setpoint value, the measurement system and the determination system being connected to the processor unit. 13. An aircraft, wherein the aircraft includes a pitching stabilizer system according to claim 12.