Force feedback control for active stabilization of synchronous whirl orbits in rotor systems with non-linear stiffness elements
Synchronous vibration in rotor systems having bearings, seals or other elements with non-linear stiffness characteristics is prone to amplitude jump when operating close to critical speeds as there may be two or more possible whirl responses for a given unbalance condition. This paper describes rese...
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2017
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th-cmuir.6653943832-431582017-09-28T06:51:12Z Force feedback control for active stabilization of synchronous whirl orbits in rotor systems with non-linear stiffness elements Cole M. Chamroon C. Ngamprapasom P. Synchronous vibration in rotor systems having bearings, seals or other elements with non-linear stiffness characteristics is prone to amplitude jump when operating close to critical speeds as there may be two or more possible whirl responses for a given unbalance condition. This paper describes research on the use of active control methods for eliminating this potentially undesirable behavior. A control scheme based on direct feedback of rotor-stator interaction forces is considered. Modelbased conditions for stability of low amplitude whirl, derived using Lyapunov's direct method, are used as a basis for synthesizing controller gains. Subsidiary requirements for existence of a static feedback control law that can achieve stabilization are also explained. An experimental validation is undertaken on a flexible rotor test rig where non-linear rotorstator contact interaction can occur across a small radial clearance in one transverse plane. A single radial active magnetic bearing is used to apply control forces in a separate transverse plane. The experiments confirm the conditions under which static feedback of the measured interaction force can prevent degenerate whirl responses so that the low amplitude contact-free orbit is the only possible steady-state response. The gain synthesis method leads to controllers that are physically realizable and can eliminate amplitude jump over a range of running speeds. Copyright © 2010 by ASME. 2017-09-28T06:51:12Z 2017-09-28T06:51:12Z 2010-12-01 Conference Proceeding 2-s2.0-82055161073 10.1115/GT2010-23246 https://www.scopus.com/inward/record.uri?partnerID=HzOxMe3b&scp=82055161073&origin=inward http://cmuir.cmu.ac.th/jspui/handle/6653943832/43158 |
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Synchronous vibration in rotor systems having bearings, seals or other elements with non-linear stiffness characteristics is prone to amplitude jump when operating close to critical speeds as there may be two or more possible whirl responses for a given unbalance condition. This paper describes research on the use of active control methods for eliminating this potentially undesirable behavior. A control scheme based on direct feedback of rotor-stator interaction forces is considered. Modelbased conditions for stability of low amplitude whirl, derived using Lyapunov's direct method, are used as a basis for synthesizing controller gains. Subsidiary requirements for existence of a static feedback control law that can achieve stabilization are also explained. An experimental validation is undertaken on a flexible rotor test rig where non-linear rotorstator contact interaction can occur across a small radial clearance in one transverse plane. A single radial active magnetic bearing is used to apply control forces in a separate transverse plane. The experiments confirm the conditions under which static feedback of the measured interaction force can prevent degenerate whirl responses so that the low amplitude contact-free orbit is the only possible steady-state response. The gain synthesis method leads to controllers that are physically realizable and can eliminate amplitude jump over a range of running speeds. Copyright © 2010 by ASME. |
| format |
Conference Proceeding |
| author |
Cole M. Chamroon C. Ngamprapasom P. |
| spellingShingle |
Cole M. Chamroon C. Ngamprapasom P. Force feedback control for active stabilization of synchronous whirl orbits in rotor systems with non-linear stiffness elements |
| author_facet |
Cole M. Chamroon C. Ngamprapasom P. |
| author_sort |
Cole M. |
| title |
Force feedback control for active stabilization of synchronous whirl orbits in rotor systems with non-linear stiffness elements |
| title_short |
Force feedback control for active stabilization of synchronous whirl orbits in rotor systems with non-linear stiffness elements |
| title_full |
Force feedback control for active stabilization of synchronous whirl orbits in rotor systems with non-linear stiffness elements |
| title_fullStr |
Force feedback control for active stabilization of synchronous whirl orbits in rotor systems with non-linear stiffness elements |
| title_full_unstemmed |
Force feedback control for active stabilization of synchronous whirl orbits in rotor systems with non-linear stiffness elements |
| title_sort |
force feedback control for active stabilization of synchronous whirl orbits in rotor systems with non-linear stiffness elements |
| publishDate |
2017 |
| url |
https://www.scopus.com/inward/record.uri?partnerID=HzOxMe3b&scp=82055161073&origin=inward http://cmuir.cmu.ac.th/jspui/handle/6653943832/43158 |
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1681422325650554880 |