Results on Active Damping Control of a Thin-Walled Rotating Cylinder with Piezoelectric Patch Actuation and Sensing∗

Results on Active Damping Control of a Thin-Walled Rotating Cylinder with Piezoelectric Patch Actuation and Sensing∗

© 2019 IEEE. This paper describes research on the active control of vibration in thin-walled cylindrical structures under rotation. Enhanced damping of flexural vibration may be achieved through feedback control of embedded piezoelectric patch actuators. To assess the interaction of wall vibration w...

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Main Authors: Ziv Brand, O. T. Matthew Cole
Format: Conference Proceeding
Published: 2020
Subjects:
Computer Science
Mathematics
Online Access:https://www.scopus.com/inward/record.uri?partnerID=HzOxMe3b&scp=85077787902&origin=inward
http://cmuir.cmu.ac.th/jspui/handle/6653943832/67717
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Institution: Chiang Mai University
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spelling th-cmuir.6653943832-677172020-04-02T15:10:40Z Results on Active Damping Control of a Thin-Walled Rotating Cylinder with Piezoelectric Patch Actuation and Sensing∗ Ziv Brand O. T. Matthew Cole Computer Science Mathematics © 2019 IEEE. This paper describes research on the active control of vibration in thin-walled cylindrical structures under rotation. Enhanced damping of flexural vibration may be achieved through feedback control of embedded piezoelectric patch actuators. To assess the interaction of wall vibration with actuator and sensor operation, a theoretical model of a rotating annulus is considered. This model describes the multi-mode travelling wave behavior for circumferential vibration. It is seen that, due to rotational symmetry, use of only a single actuator will lead to one of each pair of degenerate modes being uncontrollable in the non-rotating case. However, as rotational speed increases, full controllability is recovered. This is due to the transition under rotation from standing mode to travelling wave characteristics for the vibration. Experiments were conducted on a short thin-walled steel cylinder (diameter 224 mm). A collocated actuator/sensor (piezoelectric patch) pair was applied with a control law based on resonant filters to achieve enhanced damping of circumferential vibration modes up to third order (natural frequencies: 161, 443, 846 Hz). A second actuator/sensor pair was used to assess controllability and the effectiveness of the active damping control loop. The results confirm the suitability of the theoretical models and qualitative predictions of the speed-dependent control influence for the actuator/sensor pairs. 2020-04-02T15:01:49Z 2020-04-02T15:01:49Z 2019-08-01 Conference Proceeding 2-s2.0-85077787902 10.1109/CCTA.2019.8920635 https://www.scopus.com/inward/record.uri?partnerID=HzOxMe3b&scp=85077787902&origin=inward http://cmuir.cmu.ac.th/jspui/handle/6653943832/67717
institution Chiang Mai University
building Chiang Mai University Library
country Thailand
collection CMU Intellectual Repository
topic Computer Science
Mathematics
spellingShingle Computer Science
Mathematics
Ziv Brand
O. T. Matthew Cole
Results on Active Damping Control of a Thin-Walled Rotating Cylinder with Piezoelectric Patch Actuation and Sensing∗
description © 2019 IEEE. This paper describes research on the active control of vibration in thin-walled cylindrical structures under rotation. Enhanced damping of flexural vibration may be achieved through feedback control of embedded piezoelectric patch actuators. To assess the interaction of wall vibration with actuator and sensor operation, a theoretical model of a rotating annulus is considered. This model describes the multi-mode travelling wave behavior for circumferential vibration. It is seen that, due to rotational symmetry, use of only a single actuator will lead to one of each pair of degenerate modes being uncontrollable in the non-rotating case. However, as rotational speed increases, full controllability is recovered. This is due to the transition under rotation from standing mode to travelling wave characteristics for the vibration. Experiments were conducted on a short thin-walled steel cylinder (diameter 224 mm). A collocated actuator/sensor (piezoelectric patch) pair was applied with a control law based on resonant filters to achieve enhanced damping of circumferential vibration modes up to third order (natural frequencies: 161, 443, 846 Hz). A second actuator/sensor pair was used to assess controllability and the effectiveness of the active damping control loop. The results confirm the suitability of the theoretical models and qualitative predictions of the speed-dependent control influence for the actuator/sensor pairs.
format Conference Proceeding
author Ziv Brand
O. T. Matthew Cole
author_facet Ziv Brand
O. T. Matthew Cole
author_sort Ziv Brand
title Results on Active Damping Control of a Thin-Walled Rotating Cylinder with Piezoelectric Patch Actuation and Sensing∗
title_short Results on Active Damping Control of a Thin-Walled Rotating Cylinder with Piezoelectric Patch Actuation and Sensing∗
title_full Results on Active Damping Control of a Thin-Walled Rotating Cylinder with Piezoelectric Patch Actuation and Sensing∗
title_fullStr Results on Active Damping Control of a Thin-Walled Rotating Cylinder with Piezoelectric Patch Actuation and Sensing∗
title_full_unstemmed Results on Active Damping Control of a Thin-Walled Rotating Cylinder with Piezoelectric Patch Actuation and Sensing∗
title_sort results on active damping control of a thin-walled rotating cylinder with piezoelectric patch actuation and sensing∗
publishDate 2020
url https://www.scopus.com/inward/record.uri?partnerID=HzOxMe3b&scp=85077787902&origin=inward
http://cmuir.cmu.ac.th/jspui/handle/6653943832/67717
_version_ 1681426686825988096

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