Model and control system development for a distributed actuation magnetic bearing and thin-walled rotor subject to noncircularity
Copyright © 2019 by ASME This paper considers the problem of controlling the vibration of a lightweight thin-walled rotor with a distributed actuation magnetic bearing (DAMB). A theoretical flexible rotor model is developed that shows how multiharmonic vibration arises due to small noncircularity of...
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th-cmuir.6653943832-655862019-08-05T04:43:06Z Model and control system development for a distributed actuation magnetic bearing and thin-walled rotor subject to noncircularity Chakkapong Chamroon Matthew O.T. Cole Wichaphon Fakkaew Engineering Physics and Astronomy Copyright © 2019 by ASME This paper considers the problem of controlling the vibration of a lightweight thin-walled rotor with a distributed actuation magnetic bearing (DAMB). A theoretical flexible rotor model is developed that shows how multiharmonic vibration arises due to small noncircularity of the rotor cross section. This model predicts a series of resonance conditions that occur when the rotational frequency matches a subharmonic of a system natural frequency. Rotor noncircularity can be measured offline, and the measurement data used to cancel its effect on the position sensor signals used for feedback control. A drawback of this approach is that noncircularity is difficult to measure exactly and may vary over time due to changing thermal or elastic state of the rotor. Moreover, any additional multiharmonic excitation effects will not be compensated. To overcome these issues, a harmonic vibration control algorithm is applied that adaptively modifies the harmonic components of the actuator control currents to match a target vibration control performance, but without affecting the stabilizing feedback control loops. Experimental results for a short thin-walled rotor with a single DAMB are presented, which show the effectiveness of the techniques in preventing resonance during operation. By combining sensor-based noncircularity compensation with harmonic vibration control, a reduction in vibration levels can be achieved without precise knowledge of the rotor shape and with minimal bearing forces. 2019-08-05T04:36:23Z 2019-08-05T04:36:23Z 2019-10-01 Journal 15288927 10489002 2-s2.0-85066119315 10.1115/1.4043510 https://www.scopus.com/inward/record.uri?partnerID=HzOxMe3b&scp=85066119315&origin=inward http://cmuir.cmu.ac.th/jspui/handle/6653943832/65586 |
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Engineering Physics and Astronomy Chakkapong Chamroon Matthew O.T. Cole Wichaphon Fakkaew Model and control system development for a distributed actuation magnetic bearing and thin-walled rotor subject to noncircularity |
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Copyright © 2019 by ASME This paper considers the problem of controlling the vibration of a lightweight thin-walled rotor with a distributed actuation magnetic bearing (DAMB). A theoretical flexible rotor model is developed that shows how multiharmonic vibration arises due to small noncircularity of the rotor cross section. This model predicts a series of resonance conditions that occur when the rotational frequency matches a subharmonic of a system natural frequency. Rotor noncircularity can be measured offline, and the measurement data used to cancel its effect on the position sensor signals used for feedback control. A drawback of this approach is that noncircularity is difficult to measure exactly and may vary over time due to changing thermal or elastic state of the rotor. Moreover, any additional multiharmonic excitation effects will not be compensated. To overcome these issues, a harmonic vibration control algorithm is applied that adaptively modifies the harmonic components of the actuator control currents to match a target vibration control performance, but without affecting the stabilizing feedback control loops. Experimental results for a short thin-walled rotor with a single DAMB are presented, which show the effectiveness of the techniques in preventing resonance during operation. By combining sensor-based noncircularity compensation with harmonic vibration control, a reduction in vibration levels can be achieved without precise knowledge of the rotor shape and with minimal bearing forces. |
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Journal |
author |
Chakkapong Chamroon Matthew O.T. Cole Wichaphon Fakkaew |
author_facet |
Chakkapong Chamroon Matthew O.T. Cole Wichaphon Fakkaew |
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Chakkapong Chamroon |
title |
Model and control system development for a distributed actuation magnetic bearing and thin-walled rotor subject to noncircularity |
title_short |
Model and control system development for a distributed actuation magnetic bearing and thin-walled rotor subject to noncircularity |
title_full |
Model and control system development for a distributed actuation magnetic bearing and thin-walled rotor subject to noncircularity |
title_fullStr |
Model and control system development for a distributed actuation magnetic bearing and thin-walled rotor subject to noncircularity |
title_full_unstemmed |
Model and control system development for a distributed actuation magnetic bearing and thin-walled rotor subject to noncircularity |
title_sort |
model and control system development for a distributed actuation magnetic bearing and thin-walled rotor subject to noncircularity |
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2019 |
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https://www.scopus.com/inward/record.uri?partnerID=HzOxMe3b&scp=85066119315&origin=inward http://cmuir.cmu.ac.th/jspui/handle/6653943832/65586 |
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