Modeling techniques for active shape and vibration control of macro-fiber composite laminated structures

Shun Qi Zhang; Min Chen; Guo Zhong Zhao; Zhan Xi Wang; Rüdiger Schmidt; Xian Sheng Qin

doi:10.12989/sss.2017.19.6.633

Modeling techniques for active shape and vibration control of macro-fiber composite laminated structures

Shun Qi Zhang, Min Chen, Guo Zhong Zhao, Zhan Xi Wang^*, Rüdiger Schmidt, Xian Sheng Qin

^*Corresponding author for this work

School of Advanced Technology

Research output: Contribution to journal › Article › peer-review

14 Citations (Scopus)

Abstract

The complexity of macro-fiber composite (MFC) materials increasing the difficulty in simulation and analysis of MFC integrated structures. To give an accurate prediction of MFC bonded smart structures for the simulation of shape and vibration control, the paper develops a linear electro-mechanically coupled static and dynamic finite element (FE) models based on the first-order shear deformation (FOSD) hypothesis. Two different types of MFCs are modeled and analyzed, namely MFC-d31 and MFC-d33, in which the former one is dominated by the d₃₁ effect, while the latter one by the d₃₃ effect. The present model is first applied to an MFC-d33 bonded composite plate, and then is used to analyze both active shape and vibration control for MFC-d31/-d33 bonded plate with various piezoelectric fiber orientations.

Original language	English
Pages (from-to)	633-641
Number of pages	9
Journal	Smart Structures and Systems
Volume	19
Issue number	6
DOIs	https://doi.org/10.12989/sss.2017.19.6.633
Publication status	Published - Jun 2017

Keywords

Dynamic analysis
Laminated structures
Macro-fiber composite
Piezoelectric
Smart structures

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10.12989/sss.2017.19.6.633

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title = "Modeling techniques for active shape and vibration control of macro-fiber composite laminated structures",

abstract = "The complexity of macro-fiber composite (MFC) materials increasing the difficulty in simulation and analysis of MFC integrated structures. To give an accurate prediction of MFC bonded smart structures for the simulation of shape and vibration control, the paper develops a linear electro-mechanically coupled static and dynamic finite element (FE) models based on the first-order shear deformation (FOSD) hypothesis. Two different types of MFCs are modeled and analyzed, namely MFC-d31 and MFC-d33, in which the former one is dominated by the d31 effect, while the latter one by the d33 effect. The present model is first applied to an MFC-d33 bonded composite plate, and then is used to analyze both active shape and vibration control for MFC-d31/-d33 bonded plate with various piezoelectric fiber orientations.",

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author = "Zhang, {Shun Qi} and Min Chen and Zhao, {Guo Zhong} and Wang, {Zhan Xi} and R{\"u}diger Schmidt and Qin, {Xian Sheng}",

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AU - Chen, Min

AU - Zhao, Guo Zhong

AU - Wang, Zhan Xi

AU - Schmidt, Rüdiger

AU - Qin, Xian Sheng

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AB - The complexity of macro-fiber composite (MFC) materials increasing the difficulty in simulation and analysis of MFC integrated structures. To give an accurate prediction of MFC bonded smart structures for the simulation of shape and vibration control, the paper develops a linear electro-mechanically coupled static and dynamic finite element (FE) models based on the first-order shear deformation (FOSD) hypothesis. Two different types of MFCs are modeled and analyzed, namely MFC-d31 and MFC-d33, in which the former one is dominated by the d31 effect, while the latter one by the d33 effect. The present model is first applied to an MFC-d33 bonded composite plate, and then is used to analyze both active shape and vibration control for MFC-d31/-d33 bonded plate with various piezoelectric fiber orientations.

KW - Dynamic analysis

KW - Laminated structures

KW - Macro-fiber composite

KW - Piezoelectric

KW - Smart structures

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Modeling techniques for active shape and vibration control of macro-fiber composite laminated structures

Abstract

Keywords

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