Active vibration isolation using an electrical damper or an electrical dynamic absorber
Active vibration isolation using an electrical damper or an electrical dynamic absorber
This paper describes a theoretical and experimental study to show how an electrical damper or an electrical dynamic absorber, implemented using an electromagnetic actuator and an accelerometer, can control vibration transmission through a vibration isolator. The electrical damper is realized by feeding back the equipment velocity to the actuator with constant gain. The electrical dynamic absorber is realized by feeding back the equipment acceleration through a second-order low-pass filter. Because it is found that the plant on a flexible base is asymptotically similar to that on a rigid base, the optimal parameters of the control filter are determined analytically, independent of the base dynamics. Experimental results show that the electrical dynamic absorber has a similar performance to the electrical damper. The maximum reduction in transmitted vibration achieved was about 38 dB for both methods. It is also shown that the electrical dynamic absorber is more robust to undesirable dynamics outside the control bandwidth. Another advantage of the electrical dynamic absorber is that it does not require an integrator to transform acceleration into velocity.
245-254
Kim, Sang-Myeong
b0cee70c-c830-4294-8258-a99b3094be7d
Pietrzko, S.
5e2f52f8-f240-4e24-bb54-021d0fefc25f
Brennan, M.J.
87c7bca3-a9e5-46aa-9153-34c712355a13
March 2008
Kim, Sang-Myeong
b0cee70c-c830-4294-8258-a99b3094be7d
Pietrzko, S.
5e2f52f8-f240-4e24-bb54-021d0fefc25f
Brennan, M.J.
87c7bca3-a9e5-46aa-9153-34c712355a13
Kim, Sang-Myeong, Pietrzko, S. and Brennan, M.J.
(2008)
Active vibration isolation using an electrical damper or an electrical dynamic absorber.
IEEE Transactions on Control Systems Technology, 16 (2), .
(doi:10.1109/TCST.2007.903376).
Abstract
This paper describes a theoretical and experimental study to show how an electrical damper or an electrical dynamic absorber, implemented using an electromagnetic actuator and an accelerometer, can control vibration transmission through a vibration isolator. The electrical damper is realized by feeding back the equipment velocity to the actuator with constant gain. The electrical dynamic absorber is realized by feeding back the equipment acceleration through a second-order low-pass filter. Because it is found that the plant on a flexible base is asymptotically similar to that on a rigid base, the optimal parameters of the control filter are determined analytically, independent of the base dynamics. Experimental results show that the electrical dynamic absorber has a similar performance to the electrical damper. The maximum reduction in transmitted vibration achieved was about 38 dB for both methods. It is also shown that the electrical dynamic absorber is more robust to undesirable dynamics outside the control bandwidth. Another advantage of the electrical dynamic absorber is that it does not require an integrator to transform acceleration into velocity.
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Published date: March 2008
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Local EPrints ID: 65245
URI: http://eprints.soton.ac.uk/id/eprint/65245
ISSN: 1063-6536
PURE UUID: 5fbbc6a1-29b3-4836-896f-15225ab8e30c
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Date deposited: 13 Feb 2009
Last modified: 15 Mar 2024 12:07
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Author:
Sang-Myeong Kim
Author:
S. Pietrzko
Author:
M.J. Brennan
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