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Active flutter control of delaminated composite plate using active fiber composite patches

The effect of delamination on flutter characteristics of delaminated plate and control of flutter velocity is presented in this paper. The structural model of the smart delaminated plate is constructed using a 3D degenerated element, where the shear deformation and rotary inertia are considered base...

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Published in:	Thin-walled structures 2022-03, Vol.172, p.108856, Article 108856
Main Authors:	Swain, Prasant Kumar, Tiwari, Pratik, Maiti, Dipak Kumar, Singh, Bhrigu Nath, Maity, Damodar
Format:	Article
Language:	English
Subjects:	3-D degenerated elements Active fiber composite layer Delamination Flutter analysis
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cited_by	cdi_FETCH-LOGICAL-c297t-ccf8bf9108a52b116725f8f59a5400b5e470aa1801310cdf086831efed6ecbc33
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container_title	Thin-walled structures
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creator	Swain, Prasant Kumar Tiwari, Pratik Maiti, Dipak Kumar Singh, Bhrigu Nath Maity, Damodar
description	The effect of delamination on flutter characteristics of delaminated plate and control of flutter velocity is presented in this paper. The structural model of the smart delaminated plate is constructed using a 3D degenerated element, where the shear deformation and rotary inertia are considered based on the Reissner–Mindlin assumptions. Using the modal output of the structural model through a direct matrix abstraction program (DMAP), aerodynamic forces are generated from MSC.Nastran. Further flutter analysis is carried out using the pk-method in the MATLAB environment. This MSC.Nastran coupled FE model is thoroughly validated with various examples of dynamic and aeroelastic analysis. The effect of delamination location and interface on flutter characteristics of laminated plate with various boundary conditions are investigated first, and an attempt is made to enhance flutter velocity of the delaminated plate through active control technique. •A coupled model of FE coding and MSC.Nastran is constructed in MATLAB.•The model is developed to perform flutter analysis of smart delaminated plate.•Both embedded and through-width delamination is considered for the investigation.•The effect of location, and interface of delamination is studied.•The investigation is carried out for C-F-C-F and C-F-F-F boundary condition.•The AFC patches with interdigitated electrodes are used as sensor and actuator.•Active control technique is found to be effective for control of flutter.•The regain of flutter velocity lost due to 16.66% delamination is attempted.
doi_str_mv	10.1016/j.tws.2021.108856
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The effect of delamination location and interface on flutter characteristics of laminated plate with various boundary conditions are investigated first, and an attempt is made to enhance flutter velocity of the delaminated plate through active control technique. •A coupled model of FE coding and MSC.Nastran is constructed in MATLAB.•The model is developed to perform flutter analysis of smart delaminated plate.•Both embedded and through-width delamination is considered for the investigation.•The effect of location, and interface of delamination is studied.•The investigation is carried out for C-F-C-F and C-F-F-F boundary condition.•The AFC patches with interdigitated electrodes are used as sensor and actuator.•Active control technique is found to be effective for control of flutter.•The regain of flutter velocity lost due to 16.66% delamination is attempted.</abstract><pub>Elsevier Ltd</pub><doi>10.1016/j.tws.2021.108856</doi><orcidid>https://orcid.org/0000-0001-7902-9698</orcidid></addata></record>
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subjects	3-D degenerated elements Active fiber composite layer Delamination Flutter analysis
title	Active flutter control of delaminated composite plate using active fiber composite patches
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