Device for assisting in piloting a hybrid helicopter, a hybrid helicopter provided with such a device, and a method implemented by said device
원문보기
IPC분류정보
국가/구분
United States(US) Patent
등록
국제특허분류(IPC7판)
B64C-027/22
B64C-027/04
B64C-027/26
B64C-027/28
B64D-043/00
출원번호
US-0773965
(2010-05-05)
등록번호
US-9216820
(2015-12-22)
우선권정보
FR-09 02683 (2009-06-04)
발명자
/ 주소
Eglin, Paul
출원인 / 주소
Airbus Helicopters
대리인 / 주소
Brooks Kushman P.C.
인용정보
피인용 횟수 :
2인용 특허 :
4
초록▼
A piloting assistance device for a hybrid helicopter is provided with a rotary wing, two half-wings (8′, 8″) provided respectively with first and second propellers (6′, 6″), and an engine installation continuously driving the rotary wing (100) and the propellers by meshing with a mechanical intercon
A piloting assistance device for a hybrid helicopter is provided with a rotary wing, two half-wings (8′, 8″) provided respectively with first and second propellers (6′, 6″), and an engine installation continuously driving the rotary wing (100) and the propellers by meshing with a mechanical interconnection system. Furthermore, the device is provided with computer element (40) for determining maximum mean pitch (max) applicable to the first and second propellers without exceeding the power available for the propellers, the computer element determining the maximum mean pitch (max) as a function of the current mean pitch of the blades of the first and second propellers as measured in real time, of a maximum power that can be delivered by the engine installation, of a current power being delivered by the engine installation, and of a relationship determining a power gradient (GRD) as a function of pitch for the first and second propellers.
대표청구항▼
1. A piloting assistance device for a hybrid helicopter having a rotary wing (100) including at least one main rotor, first and second half-wings (8′, 8″) provided respectively with first and second propellers (6′, 6″), and an engine installation (5′) having at least one turbine engine (5) continuou
1. A piloting assistance device for a hybrid helicopter having a rotary wing (100) including at least one main rotor, first and second half-wings (8′, 8″) provided respectively with first and second propellers (6′, 6″), and an engine installation (5′) having at least one turbine engine (5) continuously driving said rotary wing (100) and said propellers (6′, 6″) by meshing with a mechanical interconnection system, said piloting assistance device (20) comprising: a mean pitch sensor (37) configured to measure a current mean pitch (βcur) of blades of the first and second propellers (6′, 6″) in real time;an air speed sensor (31) configured to measure true air speed (VH) of the hybrid helicopter;a speed of rotation sensor (32) configured to measure speed of rotation (Ω) of the propellers (6′, 6″) of the hybrid helicopter;a density sensor (35) configured to measure density of air in the vicinity of the hybrid helicopter;computer means (40) provided with a memory (42) containing a first equation determining a power gradient (GRD) as a function of the current mean pitch (βcur), the computer means (40) being connected to the mean pitch sensor (37), to the air speed sensor (31), to the speed of rotation sensor (32), and to the air density sensor (35), and being configured to receive first and second power values from a regulator member (34) of said engine installation (5′), said first and second power values relating respectively to a maximum power (P1) capable of being delivered by said engine installation (5′) and to a power currently being delivered (P2) by said engine installation (5′), said computer means (40) further configured to determine a maximum mean pitch (βmax) to be complied with for the blades of said first and second propellers (6′, 6″) without exceeding power available for said propellers (6′, 6″), said computer means (40) determining the maximum mean pitch (βmax) as a function of said current mean pitch (βcur), said first and second power values, and said power gradient;display means (50) configured to present said maximum mean pitch (βmax) on a display screen (60); andan autopilot device (70) configured to operate in an autopilot mode for controlling flight of the hybrid helicopter, wherein while operating in the autopilot mode the autopilot device controls the driving of said rotary wing (100) and said propellers (6′, 6″) by said least one turbine engine (5) such that the current mean pitch (βcur) does not exceed the maximum mean pitch (βmax);wherein said computer means is further configured to determine the maximum mean pitch (βmax) using the equation: βmax=βcur+[(P1*(Ω/Ω′))−P2]/GRD where: “/” represents the division sign;“*” represents the multiplication sign;“βmax” represents the maximum mean pitch;“βcur” represents the current mean pitch as measured in real time;“P1” represents the maximum power that can be delivered by the engine installation;“P2” represents the current power being delivered by the engine installation;“Ω” represents speed of rotation of said propellers;“Ω” represents a setpoint for the speed of rotation of said propellers; and“GRD” represents the power gradient. 2. The piloting assistance device according to claim 1, wherein said computer means (40) control said display means (50) to present a first symbol (55) on the display screen (60), the first symbol representing said maximum mean pitch (βmax). 3. The piloting assistance device according to claim 2, wherein said first power value is indicative of both a first maximum continuous power (PMC) capable of being delivered by said engine installation at a first mode of operation and a second maximum power (PMD) capable of being delivered by said engine installation at a second mode of operation, said computer means (40) determining a first maximum mean pitch for the first mode of operation and a second maximum mean pitch for the second mode of operation, and said computer means (40) controls said display means (50) to present on the display screen (60) a first primary symbol (55′) representing said first maximum mean pitch and a first secondary symbol (55″) representing said second maximum mean pitch. 4. The piloting assistance device according to claim 1, wherein the air speed sensor (31) is configured to deliver a first speed value relating to the true air speed (VH) of said hybrid helicopter (1) to said computer means (40), and the speed of rotation sensor (32) is configured to deliver a second speed value relating to the speed of rotation (Ω) of said propellers (6′, 6″) to said computer means (40), said computer means (40) determining an autorotation mean pitch (β0) generating zero thrust for the first and second propellers (6′, 6″) as a function of the first and second speed values. 5. The piloting assistance device according to claim 4, wherein said computer means (40) control said display means (50) to display on the display screen (60) a second symbol (56) representing said autorotation mean pitch (β0). 6. The piloting assistance device according to claim 4, wherein said computer means (40) control said display means (50) to present on the display screen (60) a second symbol (56) representing said autorotation mean pitch (β0): if said autorotation mean pitch (β0) is greater than 5 degrees; andif the measured true air speed (VH) is greater than 20 meters per second. 7. The piloting assistance device according to claim 1, wherein the computer means (40) is further configured to control the display means (50) to present a third symbol (57) on said display screen (60), said third symbol (57) relating to a pitch setpoint given by an autopilot device (70) of said hybrid helicopter (1). 8. A hybrid helicopter (1) comprising: a hybrid helicopter sub-assembly including a rotary wing (100) provided with at least one main rotor, first and second half-wings (8′, 8″) provided respectively with first and second propellers (6′, 6″), and an engine installation (5′) having at least one turbine engine (5) continuously driving said rotary wing (100) and said propellers (6′, 6″) by meshing with a mechanical interconnection system between the at least one turbine engine, the at least one main rotor, and the propellers to deliver a power, the engine installation further having a regulator member (34) configured to output a first power value relating to a maximum power (P1) capable of being delivered by said engine installation and a second power value relating to a power (P2) currently being delivered by said engine installation;a piloting assistance device having a mean pitch sensor (37) configured to measure a current mean pitch (βcur) of blades of the propellers (6′, 6″);the piloting assistance device further having computer means provided with a memory containing a first equation determining a power gradient (GRD) as a function of the current mean pitch (βcur), the computer means being connected to the mean pitch sensor and being configured to receive first and second power values from a regulator member (34) of said engine installation (5′), said computer means further configured to determine a maximum mean pitch (βmax) to be complied with for the blades of said propellers (6′, 6″) without exceeding power available for said propellers (6′, 6″), said computer means (40) determining the maximum mean pitch (βmax) as a function of said current mean pitch (βcur), said first and second power values, and said power gradient;the piloting assistance device further having a display screen configured to present said maximum mean pitch (βmax);wherein said computer means is further configured to determine the maximum mean pitch (βmax) using the equation: βmax=βcur+[(P1*(Ω/Ω′))−P2]/GRD where: “/” represents the division sign;“*” represents the multiplication sign;“βmax” represents the maximum mean pitch;“βcur” represents the current mean pitch as measured in real time;“P1” represents the maximum power that can be delivered by the engine installation;“P2” represents the current power being delivered by the engine installation;“Ω” represents speed of rotation of said propellers;“Ω′” represents a setpoint for the speed of rotation of said propellers; and“GRD” represents the power gradient. 9. A method of assisting the piloting of a hybrid helicopter (1) that is provided with a rotary wing (100) provided with at least one main rotor, first and second half-wings (8′, 8″) provided respectively with first and second propellers (6′, 6″), and an engine installation (5′) having at least one turbine engine (5), the method comprising: continuously driving the rotary wing (100) and the propellers (6′, 6″) with the at least one turbine engine (5) of the engine installation (5′) to deliver a power;measuring a current mean pitch (βcur) of blades of the propellers (6′, 6″);determining, by a computer, a power gradient (GRD) as a function of the current mean pitch (βcur);determining, by the computer, a maximum mean pitch (βmax) to be complied with for the blades of said first and second propellers (6′, 6″) without exceeding power available for said propellers (6′, 6″), wherein the maximum mean pitch (βmax) is determined by the computer as a function of the current mean pitch (βcur), a maximum power (P1) that can be delivered by said engine installation, a current power (P2) being delivered by said engine installation, and the power gradient (GRD); andpresenting said maximum mean pitch (βmax) on a display screen;wherein determining the maximum mean pitch (βmax) includes using the equation: βmax=βcur+[(P1*(Ω/Ω′))−P2]/GRD where: “/” represents the division sign;“*” represents the multiplication sign;“βmax” represents the maximum mean pitch;“βcur” represents the current mean pitch as measured in real time;“P1” represents the maximum power that can be delivered by the engine installation;“P2” represents the current power being delivered by the engine installation;“Ω” represents speed of rotation of said propellers;“Ω′” represents a setpoint for the speed of rotation of said propellers; and“GRD” represents the power gradient. 10. The method according to claim 9, wherein determining the power gradient (GRD) as a function of the current mean pitch (βcur) includes using the equation: GRD=0.5×ρ×π×R2×U3×∂CP∂β(0.75βcur,λ) where: ρ is the density of air in the vicinity of the hybrid helicopter, U is the speed of a free end of a blade of the propellers, R is the span of the blade of the propellers, CP is a power coefficient, ∂CP∂β represents the partial derivative of the power coefficient relative to the current mean pitch, βcur represents the current mean pitch, and λ represents an advance coefficient as a function of the quotient of true air speed (VH) of the hybrid helicopter divided by the speed (U) of the free end of the blade of the propellers. 11. The method according to claim 9, wherein there is determined and displayed on said display screen (60) an autorotation mean pitch (β0) as a function of the true air speed (VH) of said hybrid helicopter (1) and of the speed of rotation (Ω) of said propellers (6′, 6″) using the following second relationship: β0=α0+arctan [VH/(Ω*0.75*R)] where: “/” represents the division sign;“*” represents the multiplication sign;“arctan” represents the arc tangent trigonometric function;“β0” represents the autorotation mean pitch;“α0” represents the angle of incidence of a blade of a propeller that would generate zero lift by said blade;“VH” represents the true air speed of the hybrid helicopter;“Ω” represents the speed of rotation of said propellers; and“R” represents the span of said blade.
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이 특허에 인용된 특허 (4)
Andre, Joan; Joye, Jacky; Malagoli, Armand; Moulis, Fran?ois, Flight control indicator for an aircraft, in particular a transport airplane, intended to supply the thrust generated by at least one engine of the aircraft.
Vallart, Jean-Baptiste; Hellio, Patrick; Gauthier, Patricia; Taheri, Setareh, Flight instrument displaying a variable rotational speed of a main rotor of an aircraft.
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