An active vibration absorber is provided for absorbing vibrations in a member. An inertial mass is mounted on the member with a stiffness between the member and the mass. A force actuator arrangement applies a force between the inertial mass and the member. A damping arrangement provides for damping
An active vibration absorber is provided for absorbing vibrations in a member. An inertial mass is mounted on the member with a stiffness between the member and the mass. A force actuator arrangement applies a force between the inertial mass and the member. A damping arrangement provides for damping of a resonance of the active vibration absorber. A first sensor arrangement provides at least one first signal indicative of at least one movement and/or stress related parameter for the member and a second sensor arrangement provides for at least one second signal indicative of a reaction of the inertial mass. A control arrangement is provided for controlling the force actuator arrangement using the at least one first signal and the at least one second signal.
대표청구항▼
Therefore, having thus described the invention, at least the following is claimed: 1. An active vibration absorber for absorbing vibrations in a member, the active vibration absorber comprising: an inertial mass for mounting on said member with a stiffness therebetween; a force actuator arrangement
Therefore, having thus described the invention, at least the following is claimed: 1. An active vibration absorber for absorbing vibrations in a member, the active vibration absorber comprising: an inertial mass for mounting on said member with a stiffness therebetween; a force actuator arrangement for applying a force between said inertial mass and said member; a damping arrangement for providing damping of a resonance of said active vibration absorber; a first sensor arrangement for providing at least one first signal indicative of at least one movement and/or stress related parameter for said member; a second sensor arrangement for providing at least one second signal indicative of a reaction of said inertial mass; and a control arrangement for controlling said force actuator arrangement using said at least one first signal and said at least one second signal. 2. An active vibration absorber according to claim 1, including a stiffness arrangement for mounting said inertial mass to said member with stiffness therebetween. 3. An active vibration absorber according to claim 2, wherein said stiffness arrangement comprises a spring arrangement. 4. An active vibration absorber according to claim 1, wherein said force actuator arrangement is adapted to provide the stiff mounting of said inertial mass to said member. 5. An active vibration absorber according to claim 1, wherein said control arrangement comprises a first filter arrangement for filtering said at least one first signal, a second filter arrangement for filtering said at least one second signal, and a combining arrangement for combining outputs of said first and second filter arrangements for output to control said force actuator arrangement. 6. An active vibration absorber according to claim 5, wherein said second filter arrangement comprises an adaptive filter arrangement adaptive in response to said at least one first signal. 7. An active vibration absorber according to claim 5, wherein said first filter arrangement comprises an adaptive filter arrangement adaptive in response to said at least one first signal. 8. An active vibration absorber according to claim 1, wherein said damping arrangement comprises a third sensor arrangement for providing at least one third signal indicative of a velocity of said inertial mass, and a damping control arrangement adapted to use said third signal to control said force actuator arrangement to provide damping of a resonance of said active vibration absorber. 9. An active vibration absorber according to claim 1, wherein said second sensor arrangement is adapted to provide said at least one second signal to be indicative of a velocity of said inertial mass, and said damping arrangement comprises a damping control arrangement adapted to use said second signal to control said force actuator arrangement to provide damping of a resonance of said active vibration absorber. 10. An active vibration absorber according to claim 1, wherein said damping arrangement comprises a mechanical or fluid damping arrangement for connection between said inertial mass and said member. 11. An active vibration absorber for absorbing vibrations in a member, the active vibration absorber comprising: an inertial mass for mounting on said member with a stiffness therebetween; a force actuator arrangement for applying a force between said inertial mass and said member; a first sensor arrangement for providing at least one first signal indicative of a velocity of said inertial mass; a damping control arrangement for controlling a damping of a resonance of said active vibration absorber by controlling said force actuator arrangement using said at least one first signal; a second sensor arrangement for providing at least one second signal indicative of at least one of movement and/or stress related parameters for said member; and a feedback control arrangement for controlling said force actuator arrangement using said at least one second signal to reduce the movement and/or stress in said member. 12. An active vibration absorber according to claim 11, including a stiffness arrangement for mounting said inertial mass to said member with stiffness therebetween. 13. An active vibration absorber according to claim 12, wherein said stiffness arrangement comprises a spring arrangement. 14. An active vibration absorber according to claim 11, wherein said force actuator arrangement is adapted to provide the stiff mounting of said inertial mass to said member. 15. An active vibration absorber according to claim 11, wherein said feedback control arrangement comprises a filter arrangement for filtering said at least one second signal to generate a control signal for said force control arrangement. 16. An active vibration absorber according to claim 15, wherein said filter arrangement comprises an adaptive filter arrangement adaptive in response to said at least one second signal. 17. A method of absorbing vibrations in a member, the method comprising: mounting an inertial mass on said member with a stiffness therebetween; applying a force between said inertial mass and said member using a force actuator arrangement; damping a resonance of said inertial mass; providing at least one first signal indicative of at least one movement and/or stress related parameter for said member; providing at least one second signal indicative of a reaction of said inertial mass; and controlling the application of said force using said at least one first signal and said at least one second signal. 18. A method according to claim 17, wherein said inertial mass is mounted on said member using a spring arrangement to provide the stiffness. 19. A method according to claim 17, wherein said inertial mass is mounted on said force actuator arrangement to provide the stiff mounting of said inertial mass to said member. 20. A method according to claim 17, wherein said controlling takes place by filtering said at least one first signal using a first filter arrangement, filtering said at least one second signal using a second filter arrangement, and combining outputs of said first and second filter arrangements for output to control said force actuator arrangement. 21. A method according to claim 20, wherein said second filter arrangement is adapted in response to said at least one first signal. 22. A method according to claim 20 wherein said first filter arrangement is adapted in response to said at least one first signal. 23. A method according to claim 17, wherein said damping comprises providing at least one third signal indicative of a velocity of said inertial mass, and using said third signal to control said force actuator arrangement to provide damping of a resonance of said inertial mass. 24. A method according to claim 17, wherein said at least one second signal is indicative of a velocity of said inertial mass, and said damping comprises using said second signal to control said force actuator arrangement to provide damping of a resonance of said inertial mass. 25. A method according to claim 17, wherein said damping is carried out using a mechanical or fluid damping arrangement connected between said inertial mass and said member. 26. A method of absorbing vibrations in a member, the method comprising: mounting an inertial mass on said member with a stiffness therebetween; applying a force between said inertial mass and said member using a force actuator arrangement; providing at least one first signal indicative of a velocity of said inertial mass; controlling a damping of a resonance of said inertial mass by controlling said force actuator arrangement using said at least one first signal; providing at least one second signal indicative of at least one movement and/or stress related parameter for said member; and controlling said force actuator arrangement using said at least one second signal to reduce the movement and/or stress in said member. 27. A method according to claim 26, wherein said inertial mass is mounted on said member using a spring arrangement to provide the stiffness. 28. A method according to claim 26, wherein said inertial mass is mounted on said force actuator arrangement to provide the stiff mounting of said inertial mass to said member. 29. A method according to claim 26, wherein said controlling of said force actuator comprises filtering said at least one second signal using a filter arrangement to generate a control signal for said force control arrangement. 30. A method according to claim 29, wherein said filter arrangement is adapted in response to said at least one second signal.
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이 특허에 인용된 특허 (10)
Kurabayashi Hiroshi (575-28 ; Nakanokuki Tokyo JPX) Omi Toshio (575-28 ; Nakanokuki Tokyo JPX) Miyano Hiroshi (575-28 ; Nakanokuki Tokyo JPX) Fujita Takafumi (575-28 ; Nakanokuki Nagareyama-shi ; Chi, Active/passive damping apparatus.
Garnjost Kenneth D. (Buffalo NY) Rauch Christopher A. (Holland NY) Rey Gonzalo J. (Batavia NY), Method and apparatus for actively adjusting and controlling a resonant mass-spring system.
Rossetti Dino J. ; Jolly Mark R. ; Norris Mark A., Method and apparatus for non-model based decentralized adaptive feedforward active vibration control.
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