Method of determining the longitudinal air speed and the longitudinal ground speed of a rotary wing aircraft depending on its exposure to the wind
원문보기
IPC분류정보
국가/구분
United States(US) Patent
등록
국제특허분류(IPC7판)
B64D-043/02
B64C-013/04
B64C-013/18
B64C-013/22
G05D-001/08
출원번호
US-0163834
(2016-05-25)
등록번호
US-9862500
(2018-01-09)
우선권정보
FR-15 01096 (2015-05-28)
발명자
/ 주소
Salesse-Lavergne, Marc
출원인 / 주소
AIRBUS HELICOPTERS
대리인 / 주소
Brooks Kushman P.C.
인용정보
피인용 횟수 :
0인용 특허 :
6
초록▼
A method of determining the longitudinal air speed VairX and the longitudinal ground speed VsolX of a rotary wing aircraft depending on the exposure of the aircraft to the wind, the aircraft flying at a speed of advance Va. The method making it possible to determine characteristic speed curves for t
A method of determining the longitudinal air speed VairX and the longitudinal ground speed VsolX of a rotary wing aircraft depending on the exposure of the aircraft to the wind, the aircraft flying at a speed of advance Va. The method making it possible to determine characteristic speed curves for the aircraft depending on the longitudinal speed of the relative wind to which the aircraft is subjected, and then during a flight and depending on the actions of the pilot of the aircraft, to deduce the longitudinal ground speed VsolX and the longitudinal air speed VairX to be applied to the aircraft depending on variations in the longitudinal speed of the relative wind to which the aircraft is subjected.
대표청구항▼
1. A method of determining the longitudinal air speed VairX and the longitudinal ground speed VsolX of a rotary wing aircraft depending on the exposure to the wind of the aircraft, the aircraft flying along a track Tsol relative to the ground with a speed of advance Va, which speed of advance Va may
1. A method of determining the longitudinal air speed VairX and the longitudinal ground speed VsolX of a rotary wing aircraft depending on the exposure to the wind of the aircraft, the aircraft flying along a track Tsol relative to the ground with a speed of advance Va, which speed of advance Va may be determined relative to the ground in order to form a ground speed Vsol and relative to the air in order to form an air speed Vair, a longitudinal direction X extending from the rear of the aircraft towards the front of the aircraft, an elevation direction Z extending upwards perpendicularly to the longitudinal direction X, and a transverse direction Y extending from right to left perpendicularly to the longitudinal and elevation directions X and Z, the aircraft comprising: an autopilot for generating control signals in compliance with predefined modes of operation and in compliance with flight setpoints, the control signals being capable of causing the aircraft to perform movements in rotation and/or translation relative to the directions (X, Y, Z);at least one control means enabling a pilot of the aircraft to pilot the aircraft by transparency while the autopilot is in operation; andat least one computer and at least one memory;wherein the memory stores characteristic speed curves for the aircraft defining the longitudinal ground speed VsolX and the longitudinal air speed VairX of the aircraft as a function of a longitudinal speed of the relative wind to which the aircraft is being subjected, each characteristic speed curve corresponding to a stage of flight of the aircraft and being made up of operating points of the aircraft, each operating point being characterized by a longitudinal ground speed VsolX and by a longitudinal air speed VairX in a coordinate system having a longitudinal ground speed VsolX of the aircraft up the ordinate axis and the longitudinal air speed VairX of the aircraft along an abscissa axis, a stage of flight corresponding to a flight of the aircraft during which a pilot of the aircraft does not cause any acceleration or deceleration of the aircraft along the longitudinal direction X, the method comprising the following steps:during an initialization step, for a current stage of flight of the aircraft, identifying an initial characteristic speed curve on which the current operating point of the aircraft lies;for the current stage of flight, controlling the longitudinal air and ground speeds VairX and VsolX of the aircraft as a function of the variation of the total speed of the wind on the longitudinal direction X so that the current operating point of the aircraft moves on the initial characteristic speed curve; andfollowing the pilot taking action on the longitudinal direction to cause the aircraft to accelerate or decelerate, identifying a new characteristic speed curve on which the current operating point of the aircraft lies once the longitudinal air and ground speeds VairX and VsolX have stabilized and are substantially constant. 2. A method according to claim 1, wherein a setpoint is applied to the autopilot for a longitudinal speed of advance Vc equal to the longitudinal ground speed VsolX corresponding to the current operating point, or else for a longitudinal air speed VairX corresponding to the current operating point, depending on the longitudinal speed of the wind and on the position of the current operating point on the characteristic speed curve. 3. A method according to claim 1, wherein each characteristic speed curve is made up of a horizontal first segment corresponding to a constant longitudinal ground speed VsolX, a circular arc, and a vertical second segment corresponding to a constant longitudinal air speed VairX. 4. A method according to claim 3, wherein the setpoint forward speed of advance Vc applied to the autopilot is equal to the longitudinal ground speed VsolX of the operating point when the operating point is situated on the first segment or on a first portion of the circular arc situated between the first segment and a transition point of the circular arc, and the setpoint longitudinal speed of advance Vc applied to the autopilot is equal to the longitudinal air speed VairX of the operating point when the operating point is situated on the second segment or on a second portion of the circular arc situated between the transition point of the circular arc and the second segment. 5. A method according to claim 1, wherein the setpoint longitudinal speed of advance Vc applied to the autopilot is equal to the longitudinal air speed VairX independently of the longitudinal speed of the relative wind to which the aircraft is subjected when the longitudinal air speed VairX is greater than a maximum longitudinal air speed VairXMax. 6. A method according to claim 1, wherein the longitudinal ground speed VsolX is greater than or equal to a minimum longitudinal ground speed VsolXMin. 7. A method according to claim 6, wherein when the longitudinal ground speed VsolX is equal to a minimum longitudinal ground speed VsolXMin and the longitudinal speed of the relative wind to which the aircraft is subjected decreases in signed value, the characteristic speed curve for the aircraft that is to be taken into account changes, the setpoint longitudinal speed of advance Vc being such that the longitudinal air speed VairX increases and the longitudinal ground speed VsolX is equal to the minimum longitudinal air speed VsolXMin. 8. A method according to claim 1, wherein the longitudinal air speed VairX is greater than or equal to a minimum longitudinal air speed VairXMin in order to avoid the aircraft operating in a mass of air that has already been churned by a main rotor of the aircraft which would then risk generating a loss of lift from the main rotor. 9. A method according to claim 8, wherein the minimum air speed VairXMin is variable as a function of the modulus of the total speed of the relative wind to which the aircraft is subjected. 10. A method according to claim 8, wherein when the longitudinal air speed VairX is equal to the minimum longitudinal air speed VairXMin and the longitudinal speed of the relative wind to which the aircraft is subjected increases in signed value, the characteristic speed curve for the aircraft that is to be taken into account changes, the setpoint longitudinal speed of advance Vc being such that the longitudinal ground speed VsolX increases and the longitudinal air speed VairX is equal to the minimum longitudinal air speed VairXMin. 11. A method according to claim 1, wherein when the longitudinal air speed VairX is equal to the minimum longitudinal air speed VairXMin or when the longitudinal ground speed VsolX is equal to a minimum longitudinal ground speed VsolXMin, the characteristic speed curve to be taken into account is changed when a variation in the longitudinal speed of the relative wind to which the aircraft is subjected is greater than or equal to a protective threshold. 12. A method according to claim 1, wherein when the longitudinal air speed VairX is equal to the minimum longitudinal air speed VairXMin or when the longitudinal ground speed VsolX is equal to a minimum longitudinal ground speed VsolXMin, the characteristic speed curve to be taken into account is changed when a longitudinal speed of the relative wind to which the aircraft is subjected varies relative to a threshold with hysteresis. 13. A method according to claim 8, wherein when the longitudinal air speed VairX is equal to the minimum longitudinal air speed VairXMin and the pilot of the aircraft voluntarily reduces the longitudinal air speed VairX to below the minimum longitudinal air speed VairXMin, a new minimum longitudinal air speed VairXMin2 is defined as being equal to the longitudinal air speed VairX selected by the pilot minus a predetermined value Vδ and replaces the minimum longitudinal air speed VairXMin until the longitudinal air speed VairX becomes greater than or equal to the minimum longitudinal air speed VairXMin plus the predetermined value Vδ. 14. A method according to claim 6, wherein when the longitudinal ground speed VsolX is equal to the minimum longitudinal ground speed VsolXMin and the pilot of the aircraft voluntarily reduces the longitudinal ground speed VsolX below the minimum longitudinal ground speed VsolXMin, the longitudinal ground speed VsolX is maintained in compliance with the controls issued by the pilot. 15. A system for determining the longitudinal air speed VairX and the longitudinal ground speed VsolX of a rotary wing aircraft depending on the exposure to the wind of the aircraft, the aircraft flying along a track Tsol relative to the ground with a speed of advance Va, the speed of advance Va potentially being determined relative to the ground to form a ground speed Vsol and relative to the air to form an air speed Vair, a longitudinal direction X extending from the rear of the aircraft towards the front of the aircraft, a direction in elevation Z extending upwards perpendicularly to the longitudinal direction X, and a transverse direction Y extending from right to left perpendicularly to the longitudinal and elevation directions X and Z, the aircraft comprising: an autopilot for generating control signals in predefined modes of operation and in compliance with flight setpoints, the control signals being capable of causing the aircraft to move in rotation and/or translation relative to the directions (X, Y, Z); andat least one control means enabling the pilot to pilot the aircraft by transparency while the autopilot is in operation;the system comprising: at least one computer; andat least one memory;wherein the system for determining the longitudinal air speed VairX and the longitudinal ground speed VsolX performs the method according to claim 1.
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이 특허에 인용된 특허 (6)
Caldwell Donald G. (Mesa AZ) Osder Stephen S. (Scottsdale AZ), Automated helicopter flight control system.
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