Helicopter hub mounted vibration control and circular force generation systems for canceling vibrations
원문보기
IPC분류정보
국가/구분
United States(US) Patent
등록
국제특허분류(IPC7판)
F04D-029/26
F01D-005/26
B64C-011/00
출원번호
US-0771153
(2010-04-30)
등록번호
US-8267652
(2012-09-18)
발명자
/ 주소
Jolly, Mark R.
Black, Paul
출원인 / 주소
Lord Corporation
대리인 / 주소
Miller, Richard G.
인용정보
피인용 횟수 :
6인용 특허 :
108
초록▼
A rotary wing aircraft including a vehicle vibration control system. The vehicle vibration control system includes a rotating hub mounted vibration control system, the rotating hub mounted vibration control system mounted to the rotating rotary wing hub with the rotating hub mounted vibration contro
A rotary wing aircraft including a vehicle vibration control system. The vehicle vibration control system includes a rotating hub mounted vibration control system, the rotating hub mounted vibration control system mounted to the rotating rotary wing hub with the rotating hub mounted vibration control system rotating with the rotating rotary wing hub driven to rotate about a rotating hub center Z axis by a gear box transmission. The vehicle vibration control system includes a rotary wing aircraft member sensor for outputting rotary wing aircraft member data correlating to the relative rotation of the rotating rotary wing hub member rotating about the rotating hub center Z axis relative to the nonrotating body, a first nonrotating body vibration sensor outputting first nonrotating body vibration sensor data correlating to vibrations.
대표청구항▼
1. A rotary wing aircraft, said rotary wing aircraft having a nonrotating aerostructure body and a rotating rotary wing hub driven to rotate about a rotating hub center Z axis of rotation by an engine through a gear box transmission, said rotary wing aircraft including a vehicle vibration control sy
1. A rotary wing aircraft, said rotary wing aircraft having a nonrotating aerostructure body and a rotating rotary wing hub driven to rotate about a rotating hub center Z axis of rotation by an engine through a gear box transmission, said rotary wing aircraft including a vehicle vibration control system,a rotating hub mounted vibration control system, said rotating hub mounted vibration control system mounted to said rotating rotary wing hub with said rotating hub mounted vibration control system rotating with said rotating rotary wing hub, said rotating hub mounted vibration control system including a plurality of imbalance mass concentration rotors driven to rotate about said rotating hub center Z axis of rotation,a rotary wing aircraft member sensor for outputting rotary wing aircraft member data correlating to said relative rotation of said rotating rotary wing hub member rotating relative to said nonrotating body,at least a first nonrotating body vibration sensor, said at least first nonrotating body vibration sensor outputting at least first nonrotating body vibration sensor data correlating to vibrations,at least a first nonrotating body circular force generator having a first circular force generator rotating masses axis, said at least first nonrotating body circular force generator fixedly coupled with said nonrotating body proximate said gear box transmission with said first circular force generator rotating masses axis perpendicular to said rotating hub center Z axis of rotation,at least a second nonrotating body circular force generator having a second circular force generator rotating masses axis, said at least second nonrotating body circular force generator fixedly coupled with said nonrotating body proximate said gear box transmission with said second circular force generator rotating masses axis perpendicular to said rotating hub center Z axis of rotation,a distributed force generation data communications network link, said distributed force generation data communications system network link linking together at least said first nonrotating body circular force generator, said second nonrotating body circular force generator, and said rotating hub mounted vibration control system wherein said rotating hub mounted vibration control system and said nonrotating body circular force generators communicate force generation vibration control data through said distributed force generation data communications network,said first nonrotating body circular force generator controlled to produce a first nonrotating body circular force generator rotating force centered about said first nonrotating body circular force generator rotating masses axis with a controllable rotating force magnitude and a controllable rotating force phase, said controllable rotating force magnitude controlled from a minimal force magnitude up to a maximum force magnitude, and with said controllable rotating force phase controlled in reference to said rotary wing aircraft member sensor data correlating to said relative rotation of said rotating rotary wing hub rotating relative to said nonrotating body wherein said vibration sensed by said at least first nonrotating body vibration sensor is reduced. 2. An aircraft, as claimed in claim 1, said second nonrotating body circular force generator controlled to produce a second nonrotating body circular force generator rotating force centered about said second nonrotating body circular force generator rotating masses axis with a controllable rotating force magnitude and a controllable rotating force phase, said controllable rotating force magnitude controlled from a minimal force magnitude up to a maximum force magnitude, and with said controllable rotating force phase controlled in reference to said rotary wing aircraft member sensor data correlating to said relative rotation of said rotating rotary wing hub rotating relative to said nonrotating body wherein said vibration sensed by said at least first nonrotating body vibration sensor is reduced. 3. An aircraft, as claimed in claim 2, a third nonrotating body circular force generator having a third circular force generator rotating masses axis, said third nonrotating body circular force generator fixedly coupled with said nonrotating body proximate said gear box transmission with said third nonrotating body circular force generator rotating masses axis perpendicular to said rotating hub center Z axis of rotation,said third nonrotating body circular force generator controlled to produce a third nonrotating body circular force generator rotating force centered about said third nonrotating body circular force generator rotating masses axis with a controllable rotating force magnitude and a controllable rotating force phase, said controllable rotating force magnitude controlled from a minimal force magnitude up to a maximum force magnitude, and with said controllable rotating force phase controlled in reference to said rotary wing aircraft member sensor data correlating to said relative rotation of said rotating rotary wing hub rotating relative to said nonrotating body wherein said vibration sensed by said at least first nonrotating body vibration sensor is reduced. 4. An aircraft, as claimed in claim 3, wherein said said rotating hub mounted vibration control system, said first nonrotating body circular force generator, second nonrotating body circular force generator, and said third nonrotating body circular force generator are controlled together to provide five degrees of freedom control. 5. An aircraft, as claimed in claim 1, said rotating hub mounted vibration control system including a first rotating body vibration sensor, said rotating hub mounted vibration control system first rotating body vibration sensor outputting first rotating body vibration sensor data into said distributed force generation data communications network link. 6. An aircraft, as claimed in claim 1, wherein a master controller connected to said distributed force generation data communications network link controls said rotating hub mounted vibration control system and said first nonrotating body circular force generator wherein vibrations sensed by said at least a first nonrotating body vibration sensor are minimized. 7. An aircraft, as claimed in claim 1, wherein said distributed force generation data communications network link is a serial communications network link. 8. An aircraft, as claimed in claim 1, wherein rotating rotary wing hub has an operational rotation frequency and said rotating hub mounted vibration control system plurality of imbalance mass concentration rotors include: a first hub mounted vibration control system rotor with a first imbalance mass concentration, said first hub mounted vibration control system rotor driven to rotate at a first rotation speed greater than said operational rotation frequency of said rotating rotary wing hub,a second hub mounted vibration control system rotor with a second imbalance mass concentration, said second hub mounted vibration control system rotor driven to rotate at said first rotation speed greater than said operational rotation frequency of said rotating rotary wing hub,a third hub mounted vibration control system rotor with a third imbalance mass concentration, said third hub mounted vibration control system rotor driven to rotate at a second rotation speed greater than said operational rotation frequency of said rotating rotary wing hub,a fourth hub mounted vibration control system rotor with a fourth imbalance mass concentration, said fourth hub mounted vibration control system rotor driven to rotate at said second rotation speed greater than said operational rotation frequency of said rotating rotary wing hub. 9. An aircraft, as claimed in claim 1, wherein said rotating hub mounted vibration control system plurality of imbalance mass concentration rotors include a first hub mounted vibration control system rotor with a first imbalance mass concentration, said first hub mounted vibration control system rotor driven to rotate at a first rotor speed greater than an operational rotation frequency of said rotating rotary wing hub, a second hub mounted vibration control system rotor with a second imbalance mass concentration, said second hub mounted vibration control system rotor driven to rotate at a second rotor speed greater than said operational rotation frequency of said rotating rotary wing hub. 10. An aircraft as claimed in claim 2, said first circular force generator including a first rotating mass (mass1—1) controllably driven about said first circular force generator rotating masses axis with a first rotating mass controllable rotating imbalance phase Φ1—1 and a second corotating mass (mass1—2) controllably driven about said first circular force generator rotating masses axis with a second rotating mass controllable rotating imbalance phase Φ1—2, andsaid second circular force generator including a first rotating mass (mass2—1) controllably driven about said second circular force generator rotating masses axis with a first rotating mass controllable rotating imbalance phase Φ2—1 and a second corotating mass (mass2—2) controllably driven about said second circular force generator rotating masses axis with a second rotating mass controllable rotating imbalance phase Φ2—2, said second circular force generator oriented relative to said first circular force generator wherein said second circular force generator rotating masses axis is nonparallel with said first circular force generator rotating masses axis. 11. An aircraft vibration control system, for a aircraft vehicle having a nonrotating aerostructure body and a rotating rotary wing hub driven to rotate about a rotating hub center Z axis of rotation by an engine through a gear box transmission, including,a rotating hub mounted vibration control system, said rotating hub mounted vibration control system mounted to said rotating rotary wing hub with said rotating hub mounted vibration control system rotating about said rotating hub center Z axis of rotation with said rotating rotary wing hub,a rotary wing aircraft member sensor for outputting rotary wing aircraft member data correlating to said relative rotation of said rotating rotary wing hub member rotating relative to said nonrotating body,at least a first nonrotating body vibration sensor, said at least first nonrotating body vibration sensor outputting at least first nonrotating body vibration sensor data correlating to vibrations,at least a first nonrotating body force generator and a second nonrotating body force generator,said at least first nonrotating body force generator fixedly coupled with said nonrotating body adjacent said gear box transmission,said first nonrotating body circular force generator having a first circular force generator rotating masses axis, said at least first nonrotating body circular force generator fixedly coupled with said nonrotating body adjacent said gear box transmission with said first circular force generator rotating masses axis perpendicular to said rotating hub center Z axis of rotation,said second nonrotating body circular force generator having a second circular force generator rotating masses axis, said at least second nonrotating body circular force generator fixedly coupled with said nonrotating body adjacent said gear box transmission with said second circular force generator rotating masses axis perpendicular to said rotating hub center Z axis of rotation,said first circular force generator rotating masses axis nonparallel to said second circular force generator rotating masses axis,a distributed force generation data communications network link, said distributed force generation data communications network link linking together at least said first and second nonrotating body force generators and said rotating hub mounted vibration control system wherein said rotating hub mounted vibration control system and said first nonrotating body force generator communicate through said distributed force generation data communications network,said first nonrotating body circular force generator controlled to produce a first nonrotating body circular force generator rotating force centered about said first nonrotating body circular force generator rotating masses axis with a controllable rotating force magnitude and a controllable rotating force phase, said controllable rotating force magnitude controlled from a minimal force magnitude up to a maximum force magnitude, and with said controllable rotating force phase controlled in reference to said rotary wing aircraft member sensor data correlating to said relative rotation of said rotating rotary wing hub rotating relative to said nonrotating body, andsaid second nonrotating body circular force generator controlled to produce a second nonrotating body circular force generator rotating force centered about said second nonrotating body circular force generator rotating masses axis with a controllable rotating force magnitude and a controllable rotating force phase, said controllable rotating force magnitude controlled from a minimal force magnitude up to a maximum force magnitude, and with said controllable rotating force phase controlled in reference to said rotary wing aircraft member sensor data correlating to said relative rotation of said rotating rotary wing hub rotating relative to said nonrotating body,and said rotating hub mounted vibration control system includes at least a first hub mounted vibration control system rotor with a first imbalance mass concentration, said first hub mounted vibration control system rotor driven to rotate at a first rotation speed greater than an operational rotation frequency of said rotating rotary wing hub, and at least a second hub mounted vibration control system rotor with a second imbalance mass concentration, said second hub mounted vibration control system rotor driven to rotate at said first rotation speed greater than said operational rotation frequency of said rotating rotary wing hub,wherein said vibration sensed by said at least first nonrotating body vibration sensor is reduced. 12. An aircraft vibration control system, as claimed in claim 11, including a third nonrotating body circular force generator having a third circular force generator rotating masses axis, said third nonrotating body circular force generator fixedly coupled with said nonrotating body proximate said gear box transmission with said third nonrotating body circular force generator rotating masses axis perpendicular to said rotating hub center Z axis of rotation,said third nonrotating body circular force generator controlled to produce a third nonrotating body circular force generator rotating force centered about said third nonrotating body circular force generator rotating masses axis with a controllable rotating force magnitude and a controllable rotating force phase, said controllable rotating force magnitude controlled from a minimal force magnitude up to a maximum force magnitude, and with said controllable rotating force phase controlled in reference to said rotary wing aircraft member sensor data correlating to said relative rotation of said rotating rotary wing hub rotating relative to said nonrotating body wherein said vibration sensed by said at least first nonrotating body vibration sensor is reduced. 13. A method of controlling aircraft vibrations in a rotary wing aircraft having a nonrotating aerostructure body and a rotating rotary wing hub driven to rotate about a rotating hub center Z axis of rotation by an engine through a gear box transmission, said method including,providing a rotating hub mounted vibration control system, said rotating hub mounted vibration control system mounted to said rotating rotary wing hub with said rotating hub mounted vibration control system rotating about said rotating hub center Z axis of rotation with said rotating rotary wing hub, said rotating hub mounted vibration control system including a first hub mounted vibration control system rotor with a first imbalance mass concentration, and a second hub mounted vibration control system rotor with a second imbalance mass concentration, said second hub mounted vibration control system rotor,providing a first nonrotating body force generator,said first nonrotating body force generator fixedly coupled with said nonrotating body adjacent said gear box transmission,said first nonrotating body circular force generator having a first circular force generator rotating masses axis, with said first circular force generator rotating masses axis perpendicular to said rotating hub center Z axis of rotation,providing a second nonrotating body circular force generator having a second circular force generator rotating masses axis, said second nonrotating body circular force generator fixedly coupled with said nonrotating body adjacent said gear box transmission with said second circular force generator rotating masses axis perpendicular to said rotating hub center Z axis of rotation, with said first circular force generator rotating masses axis nonparallel to said second circular force generator rotating masses axis,controlling said first nonrotating vehicle body circular force generator to produce a rotating force with a controllable rotating force magnitude and a controllable rotating force phase,controlling said second nonrotating vehicle body circular force generator to produce a rotating force with a controllable rotating force magnitude and a controllable rotating force phase,and driving said first hub mounted vibration control system rotor and said second hub mounted vibration control system rotor to control said vibrations. 14. A method as claimed in claim 13, including providing a third nonrotating body circular force generator having a third circular force generator rotating masses axis, said third nonrotating body circular force generator fixedly coupled with said nonrotating body proximate said gear box transmission with said third nonrotating body circular force generator rotating masses axis perpendicular to said rotating hub center Z axis of rotation,and controlling said third nonrotating body circular force generator to produce a third nonrotating body circular force generator rotating force centered about said third nonrotating body circular force generator rotating masses axis with a controllable rotating force magnitude and a controllable rotating force phase, said controllable rotating force magnitude controlled from a minimal force magnitude up to a maximum force magnitude, and with said controllable rotating force phase controlled in reference to a rotary wing aircraft member sensor data correlating to said relative rotation of said rotating rotary wing hub rotating relative to said nonrotating body wherein a vibration sensed by an at least first nonrotating body vibration sensor is reduced.
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