Method of managing an engine failure on a multi-engined aircraft having a hybrid power plant
원문보기
IPC분류정보
국가/구분
United States(US) Patent
등록
국제특허분류(IPC7판)
G06F-019/00
B64C-019/00
B64C-027/14
B64D-027/24
B64D-031/00
B64D-035/02
B64D-035/08
B64D-027/02
출원번호
US-0060802
(2013-10-23)
등록번호
US-9008942
(2015-04-14)
우선권정보
FR-12 02897 (2012-10-29)
발명자
/ 주소
Dyrla, Nadine
Connaulte, Matthieu
Cezard, Joris
출원인 / 주소
Airbus Helicopters
대리인 / 주소
Brooks Kushman P.C.
인용정보
피인용 횟수 :
4인용 특허 :
4
초록▼
A method of managing an engine failure on a rotary wing aircraft (1) having a hybrid power plant (5) with at least two fuel-burning engines (13, 13′), at least one electric machine (12), and a main gearbox (11). Said aircraft (1) also has electrical energy storage means (14) and a main rotor (2) mec
A method of managing an engine failure on a rotary wing aircraft (1) having a hybrid power plant (5) with at least two fuel-burning engines (13, 13′), at least one electric machine (12), and a main gearbox (11). Said aircraft (1) also has electrical energy storage means (14) and a main rotor (2) mechanically connected to said hybrid power plant (5). In said method, during each flight, the operation of said engines (13, 13′) is monitored in order to detect a failure of any one of them, and then once a failure of one of said engines (13, 13′) has been detected, said electric machine (12) is controlled, if necessary, to deliver auxiliary power We in order to avoid a deficit appearing in the total power WT of said hybrid power plant (5), thereby enabling the pilot of said aircraft (1) to fly said aircraft (1) safely without degrading said hybrid power plant (5).
대표청구항▼
1. A method of managing an engine failure on a rotary wing aircraft, said aircraft comprising: a hybrid power plant having at least two fuel-burning engines, at least one electric machine, a main gearbox “MGB”, and at least one electronic engine control unit “EECU”, each EECU being connected to a re
1. A method of managing an engine failure on a rotary wing aircraft, said aircraft comprising: a hybrid power plant having at least two fuel-burning engines, at least one electric machine, a main gearbox “MGB”, and at least one electronic engine control unit “EECU”, each EECU being connected to a respective engine, each engine being capable of delivering at least a maximum continuous power MCP rating and OEI 30″, OEI 2′, and OEI Cont power ratings, said hybrid power plant delivering total driving power WT to said MGB;at least one electrical energy storage means; andat least one main rotor that is driven in flight at an instantaneous speed of rotation Nr by said hybrid power plant;the method being characterized by: a checking step, in which the operation of each engine is checked during each flight by means of said EECU in order to detect a failure, if any, of at least one engine, an engine being considered as having failed when at least one other engine delivers said OEI power rating;a monitoring step during which a monitoring value is determined relating to at least one monitoring parameter of said aircraft and a detection threshold is determined for detecting a deficit in said total power WT, a comparison then being performed by comparing said monitoring value with said detection threshold in order to identify a risk of a deficit in said total power WT, said deficit in the total power WT appearing whenever at least one engine needs to deliver power greater than a predetermined power WP; anda control step, during which, when a failure of at least one engine is detected and said detection threshold is crossed, said electric machine is controlled to deliver auxiliary power We so that said total driving power WT from said hybrid power plant is sufficient to fly said aircraft safely, each engine that remains operational not delivering power greater than said predetermined power WP. 2. A method according to claim 1, wherein said monitoring value is equal to said monitoring parameter. 3. A method according to claim 1, wherein said monitoring value is determined in application of a pre-established relationship combining at least two monitoring parameters. 4. A method according to claim 1, wherein a time derivative of each monitoring parameter is determined during said monitoring step, and said monitoring value is determined in application of a pre-established relationship combining at least one monitoring parameter and its time derivative. 5. A method according to claim 1, wherein said aircraft has first measurement means for measuring torque CM delivered by each engine, and a first monitoring parameter is said torque CM from each engine. 6. A method according to claim 1, wherein said engines are turboshaft engines and said aircraft has second measurement means for measuring the temperature T4 of the combustion chamber of each engine, and a second monitoring parameter is said temperature T4 of the combustion chamber of the engine. 7. A method according to claim 1, wherein said engines are turboshaft engines and said aircraft has third measurement means for measuring the instantaneous speed of rotation N1 of a compressor of each engine, and a third monitoring parameter is said instantaneous speed of rotation N1. 8. A method according to claim 7, wherein the monitoring value is the difference between said third monitoring parameters for two engines. 9. A method according to claim 1, wherein said aircraft has fourth measurement means for measuring the instantaneous speed of rotation Nr of said main rotor, and a fourth monitoring parameter is said instantaneous speed of rotation Nr. 10. A method according to claim 1, wherein said aircraft has display means, and information is displayed on said display means relating to said auxiliary power We available from said electric machine and an indication indicating whether said method is in operation. 11. A method according to claim 10, wherein said information is said maximum total driving power WT that said hybrid power plant can deliver to said MGB. 12. A method according to claim 10, wherein said information is the remaining time during which said electric machine can be used delivering a maximum power Wmax. 13. A method according to claim 1, wherein said predetermined power WP of each engine is said maximum continuous power MCP of the engine. 14. A method according to claim 1, wherein said predetermined power WP of each engine is said OEI Cont power rating of the engine. 15. A method according to claim 1, wherein said predetermined power WP of each engine is said OEI 2′ power rating of the engine. 16. A method according to claim 1, wherein said predetermined power WP of each engine is said OEI 30″ power rating of the engine. 17. A rotary wing aircraft including: a device for managing an engine failure, the device comprising:a hybrid power plant having at least two fuel-burning engines, at least one electric machine, a main gearbox “MGB”, and at least one electronic engine control unit “EECU”, each EECU being connected to a respective engine, each engine being capable of delivering at least a maximum continuous power MCP rating and OEI 30″, OEI 2′, and OEI Cont power ratings, said hybrid power plant delivering total driving power WT to said MGB;at least one electrical energy storage means; andcontrol means for controlling said electric machine;at least one main rotor driven in rotation by said hybrid power plant and rotating in flight at an instantaneous speed of rotation Nr;wherein said device includes monitoring means for determining a monitoring value relating to at least one monitoring parameter of said aircraft and for determining a detection threshold for detecting a deficit in said total power WT, and then performing a comparison by comparing said monitoring value with said detection threshold in order to identify a risk of a deficit in said total driving power WT, said deficit in the total power WT appearing whenever at least one engine needs to deliver power greater than a predetermined power WP, said control means communicating with said monitoring means and said electric machine in order to perform the method according to claim 1. 18. An aircraft according to claim 17, wherein said monitoring means include at least one measurement means for evaluating an increase in the power from each engine. 19. An aircraft according to claim 17, wherein said monitoring means include at least one measurement means for evaluating a drop in the power of said main rotor. 20. An aircraft according to claim 17, wherein said monitoring means comprise a calculation unit and a memory, said calculation unit executing instructions stored in said memory and enabling said monitoring value, and said detection threshold for detecting a deficit in said total power WT to be determined and enabling said comparison to be performed for comparing said monitoring value with said detection threshold. 21. An aircraft according to claim 17, wherein said aircraft includes display means for displaying information relating to said auxiliary power We available from said electric machine together with an indication indicating whether said device is in operation. 22. An aircraft according to claim 17, wherein said storage means comprise at least one rechargeable storage means, and said electric machine is capable of operating in generator mode in order to transform mechanical energy of said main rotor into electrical energy for charging said rechargeable storage means. 23. An aircraft according to claim 17, wherein said storage means include at least one rechargeable storage means, and said electric machine is capable of operating in generator mode in order to transform mechanical energy from at least one engine into electrical energy for charging said rechargeable storage means.
Germanetti Serge Alexandre,FRX, System for detecting and monitoring the rotational speed of at least one rotor and the rotational speed of at least one.
Vallart, Jean-Baptiste; Taheri, Setareh; Gavios, Damien; Rocheron, Celine, Assisting the piloting of a multi-engined rotorcraft in an engine-failure situation, in the context of a main rotor of the rotorcraft being driven at variable speed.
Vallart, Jean-Baptiste; Taheri, Setareh, Method of regulating the speed of rotation of the main rotor of a multi-engined rotorcraft in the event of one of the engines failing.
Vondrell, Randy M.; Polakowski, Matthew Ryan; Murrow, Kurt David; Crabtree, Glenn; Zatorski, Darek Tomasz, Tiltrotor propulsion system for an aircraft.
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