초록 ▼

A flight control system moves elevators according to a pilot command summed with an automatic command. The flight control system monitors a set of flight parameters to determine if the flight vehicle is operating inside a permitted envelope. The flight controls system incorporates automatic protecti

A flight control system moves elevators according to a pilot command summed with an automatic command. The flight control system monitors a set of flight parameters to determine if the flight vehicle is operating inside a permitted envelope. The flight controls system incorporates automatic protections thru the automatic elevator command if the flight vehicle is close to its envelope limits. The exemplary illustrative non-limiting implementation herein provides automatic protections in order to protect the flight vehicle from low speeds, high attitude, stalls and buffetings.

대표청구항 ▼

1. A flight control apparatus operable to deploy at least one control surfaces of a flight vehicle to create automatic protections in order to protect the flight vehicle, the flight control apparatus comprising: a processor;an inceptor including a command sensor to sense and deliver inceptor command

1. A flight control apparatus operable to deploy at least one control surfaces of a flight vehicle to create automatic protections in order to protect the flight vehicle, the flight control apparatus comprising: a processor;an inceptor including a command sensor to sense and deliver inceptor commands to the processor;a plurality of sensors to sense and deliver a plurality of parameters to the processor;a first transformation routine associated with the processor to transform the inceptor commands;a second transformation routine associated with the processor to transform the transformed inceptor commands into output commands;a determination routine associated with the processor to determine whether a protection is engaged; andan actuator driven by the output commands to control the at least one control surface,wherein said determination routine is capable of determining whether a stall protection, a buffeting protection, a low speed protection and/or a high attitude protection is engaged;wherein if the stall protection, the buffeting protection and/or the low speed protection is engaged, said first transformation routine is operable to transform the inceptor commands to an angle of attack reference value;wherein if the high attitude protection is engaged, said first transformation routine is operable to transform said inceptor commands to a pitch angle reference value;wherein said transformation performed by said second transformation routine depends on whether the stall protection, the buffeting protection, the low speed protection and/or the high altitude protection is engaged and is different for each of the protections; and wherein said plurality of sensors are operable to sense at least an angle of attack, an angle-of-attack rate, a mach number, a flap position, a landing gear position and an ice condition of the flight vehicle, said flight control apparatus further including: a calculation routine associated with the processor to compute an angle-of-attack threshold equal to the angle-of-attack plus a bias based at least in part on the angle-of attack rate; a computation routine associated with the processor to compute the angle-of-attack reference value based at least in part on the Mach number, the flap position, the landing gear position and the ice condition; and a comparison routine associated with the processor to compare the angle-of-attack threshold to the angle-of-attack reference value, wherein the processor is configured to use an automatic function to command the actuator if the angle-of attack threshold is larger than the angle-of-attack reference value. 2. The flight control apparatus as claimed in 1, wherein said plurality of sensors are operable to sense at least an airspeed, an airspeed rate and a flap position of the flight vehicle, said apparatus further including: a first computation routine associated with said processor to compute an airspeed threshold equal to the airspeed minus a bias based at least in part on the airspeed rate;a second computation routine associated with said processor to compute an airspeed reference value based on the flap position of the flight vehicle; anda comparison routine associated with the processor to compare the airspeed threshold to the airspeed reference value, wherein the processor is configured to use an automatic function to command the actuator if the airspeed threshold is lower than the airspeed reference value. 3. A flight control apparatus operable to deploy at least one control surface of a flight vehicle to create automatic protections in order to protect the flight vehicle, comprising: a processor;an inceptor including a command sensor to sense and deliver inceptor commands to the processor;a plurality of sensors to sense and deliver a plurality of parameters to the processor;a first transformation routine associated with the processor to transform the inceptor commands;a second transformation routine associated with the processor to transform the transformed inceptor commands into output commands;a determination routine associated with the processor to determine whether a protection is engaged; andan actuator driven by the output commands to control at least one control surface,wherein said determination routine is capable of determining whether a stall protection, a buffeting protection, a low speed protection and/or a high attitude protection is engaged;wherein if the stall protection, the buffeting protection, or the low speed protection is engaged, said first transformation routine is operable to transform said inceptor commands to an angle of attack reference value;wherein if the high attitude protection is engaged, said first transformation routine is operable to transform said inceptor commands to a pitch angle reference value; andwherein said transformation performed by said second transformation routine depends on whether the stall protection, the buffeting protection, the low speed protection and/or the high altitude of protection is engaged and is different for each of the protections,wherein said plurality of sensors are operable to sense at least an airspeed, an airspeed rate and a flap position of the flight vehicle, said flight control apparatus further including:a first computation routine associated with said processor to compute an airspeed threshold equal to the airspeed minus a bias based at least in part on the airspeed rate;a second computation routine associated with said processor to compute an airspeed reference value based on the flap position of the flight vehicle; andcomparison routine associated with the processor to compare the airspeed threshold to the airspeed reference value, wherein an automatic function is used by the processor to command the actuator if the airspeed threshold is lower than the airspeed reference value, andwherein said plurality of sensors are operable to further sense at least the throttle lever position of the flight vehicle, said apparatus further comprising:a position sensing routine associated with said processor to process the throttle lever position to define the envelope of thrust allowable in a predetermined flight control mode; anda prevention routine associated with the processor to prevent an automatic function from commanding the actuator if the throttle lever position indicates that the flight vehicle is not in the envelope of thrust allowable in the predetermined flight control mode. 4. The flight control apparatus of claim 1, wherein said plurality of sensors are operable to sense at least a pitch attitude, a pitch attitude rate, a flap position and a flight vehicle height above ground; a first computation routine associated with said processor to computes a pitch attitude threshold plus a bias based at least in part on the pitch attitude rate;a second computation routine associated with said processor to computes a pitch attitude reference value based at least in part on the flap position and the flight vehicle height above ground; anda comparison routine associated with the processor compares the pitch attitude threshold to the pitch attitude reference value, wherein the processor is configured to use an automatic function to command the actuator if the pitch attitude threshold is larger than the pitch attitude reference value. 5. The flight control apparatus of claim 1, wherein said plurality of sensors are operable to sense at least flap position, landing gear position, Mach number and altitude; and feedback, feed-forward and integral gains are adjusted according to the flap position, landing gear position, Mach number and altitude of the flight vehicle. 6. The flight control apparatus of claim 1 further comprising: a first gain adjustment routine to adjust an airspeed setting of feed-forward, feedback and integral gains when an airspeed threshold is lower than an airspeed reference value;a second gain adjustment routine to adjust an angle-of-attack setting of feed-forward, feedback and integral gains when an angle-of-attack threshold is greater than an angle-of-attack reference value;a third gain adjustment routine to adjust a pitch attitude setting of feed-forward, feedback and integral gains when a pitch attitude threshold is greater than a pitch attitude reference value; andwherein the processor is configured to use an automatic function to command the actuator according to the angle-of-attack settings of gains if the angle-of-attack threshold is larger than its reference value, according to the airspeed setting of gains if the airspeed threshold is lower than its reference value, or according to the pitch attitude gains when the pitch attitude threshold is greater than its reference value.