Investigation of actuator debonding effects on active control in smart composite laminates
This article presents a numerical study of active vibration control of smart composite laminates in the presence of actuator debonding failures. A comparison between the smart composite laminates with healthy actuator and various partially debonded actuator cases is performed to investigate the debo...
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SAGE Publishing
2015-04-01
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| Series: | Advances in Mechanical Engineering |
| Online Access: | https://doi.org/10.1177/1687814015578363 |
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doaj-0fef2d7d51354365a4335e31dfa07ec12020-11-25T03:51:58ZengSAGE PublishingAdvances in Mechanical Engineering1687-81402015-04-01710.1177/168781401557836310.1177_1687814015578363Investigation of actuator debonding effects on active control in smart composite laminatesBin Huang0Heung Soo Kim1Gil Ho Yoon2Department of Mechanical, Robotics and Energy Engineering, Dongguk University-Seoul, Seoul, Republic of KoreaDepartment of Mechanical, Robotics and Energy Engineering, Dongguk University-Seoul, Seoul, Republic of KoreaDepartment of Mechanical Engineering, Hanyang University, Seoul, Republic of KoreaThis article presents a numerical study of active vibration control of smart composite laminates in the presence of actuator debonding failures. A comparison between the smart composite laminates with healthy actuator and various partially debonded actuator cases is performed to investigate the debonding effects on the vibration suppression. The improved layerwise theory with Heaviside’s unit step function is adopted to model the displacement field with actuator debonding failure. The higher order electric potential field is adopted to describe the potential variation through the thickness. The finite element method–based formulations are derived using the plate element, taking into consideration the electro-mechanical coupling effect. The reduced-order model is represented by the state-space form and further for the vibration suppression using a simple constant gain velocity feedback control strategy. For the purpose of demonstration, a 16-layer cross-ply substrate laminate ([0/90]4s) is employed for the numerical study. The results show that the actuator debonding affects the closed-loop frequencies, active damping ratios, and efficiency of vibration suppression.https://doi.org/10.1177/1687814015578363 |
| collection |
DOAJ |
| language |
English |
| format |
Article |
| sources |
DOAJ |
| author |
Bin Huang Heung Soo Kim Gil Ho Yoon |
| spellingShingle |
Bin Huang Heung Soo Kim Gil Ho Yoon Investigation of actuator debonding effects on active control in smart composite laminates Advances in Mechanical Engineering |
| author_facet |
Bin Huang Heung Soo Kim Gil Ho Yoon |
| author_sort |
Bin Huang |
| title |
Investigation of actuator debonding effects on active control in smart composite laminates |
| title_short |
Investigation of actuator debonding effects on active control in smart composite laminates |
| title_full |
Investigation of actuator debonding effects on active control in smart composite laminates |
| title_fullStr |
Investigation of actuator debonding effects on active control in smart composite laminates |
| title_full_unstemmed |
Investigation of actuator debonding effects on active control in smart composite laminates |
| title_sort |
investigation of actuator debonding effects on active control in smart composite laminates |
| publisher |
SAGE Publishing |
| series |
Advances in Mechanical Engineering |
| issn |
1687-8140 |
| publishDate |
2015-04-01 |
| description |
This article presents a numerical study of active vibration control of smart composite laminates in the presence of actuator debonding failures. A comparison between the smart composite laminates with healthy actuator and various partially debonded actuator cases is performed to investigate the debonding effects on the vibration suppression. The improved layerwise theory with Heaviside’s unit step function is adopted to model the displacement field with actuator debonding failure. The higher order electric potential field is adopted to describe the potential variation through the thickness. The finite element method–based formulations are derived using the plate element, taking into consideration the electro-mechanical coupling effect. The reduced-order model is represented by the state-space form and further for the vibration suppression using a simple constant gain velocity feedback control strategy. For the purpose of demonstration, a 16-layer cross-ply substrate laminate ([0/90]4s) is employed for the numerical study. The results show that the actuator debonding affects the closed-loop frequencies, active damping ratios, and efficiency of vibration suppression. |
| url |
https://doi.org/10.1177/1687814015578363 |
| work_keys_str_mv |
AT binhuang investigationofactuatordebondingeffectsonactivecontrolinsmartcompositelaminates AT heungsookim investigationofactuatordebondingeffectsonactivecontrolinsmartcompositelaminates AT gilhoyoon investigationofactuatordebondingeffectsonactivecontrolinsmartcompositelaminates |
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