An efficient iterative model reduction method for aeroviscoelastic panel flutter analysis in the supersonic regime

•Supersonic panel flutter analysis of aeroelastic systems incorporating viscoelastic materials.•The iterative reduction method is a powerful tool in the flutter prediction of aeroviscoelastic systems.•An efficient iterative scheme to predict the flutter of full and reduced aeroviscoelastic systems.•...

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Veröffentlicht in:	Mechanical systems and signal processing 2018-05, Vol.104, p.575-588
Hauptverfasser:	Cunha-Filho, A.G., Briend, Y.P.J., de Lima, A.M.G., Donadon, M.V.
Format:	Artikel
Sprache:	eng
Schlagworte:	Aeroelasticity Aeronautics Cost analysis Efficiency Finite element Flutter analysis Flutter suppression Iterative methods Mathematical models Model reduction Panel flutter Passive control Predictions Reduction methods Supersonic aircraft Supersonic flow Temperature Temperature dependence Vibration Viscoelastic materials Viscoelasticity
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creator	Cunha-Filho, A.G. Briend, Y.P.J. de Lima, A.M.G. Donadon, M.V.
description	•Supersonic panel flutter analysis of aeroelastic systems incorporating viscoelastic materials.•The iterative reduction method is a powerful tool in the flutter prediction of aeroviscoelastic systems.•An efficient iterative scheme to predict the flutter of full and reduced aeroviscoelastic systems.•Verification of the proposed reduction method with those available in the open literature. The flutter boundary prediction of complex aeroelastic systems is not an easy task. In some cases, these analyses may become prohibitive due to the high computational cost and time associated with the large number of degrees of freedom of the aeroelastic models, particularly when the aeroelastic model incorporates a control strategy with the aim of suppressing the flutter phenomenon, such as the use of viscoelastic treatments. In this situation, the use of a model reduction method is essential. However, the construction of a modal reduction basis for aeroviscoelastic systems is still a challenge, owing to the inherent frequency- and temperature-dependent behavior of the viscoelastic materials. Thus, the main contribution intended for the present study is to propose an efficient and accurate iterative enriched Ritz basis to deal with aeroviscoelastic systems. The main features and capabilities of the proposed model reduction method are illustrated in the prediction of flutter boundary for a thin three-layer sandwich flat panel and a typical aeronautical stiffened panel, both under supersonic flow.
doi_str_mv	10.1016/j.ymssp.2017.11.018
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The flutter boundary prediction of complex aeroelastic systems is not an easy task. In some cases, these analyses may become prohibitive due to the high computational cost and time associated with the large number of degrees of freedom of the aeroelastic models, particularly when the aeroelastic model incorporates a control strategy with the aim of suppressing the flutter phenomenon, such as the use of viscoelastic treatments. In this situation, the use of a model reduction method is essential. However, the construction of a modal reduction basis for aeroviscoelastic systems is still a challenge, owing to the inherent frequency- and temperature-dependent behavior of the viscoelastic materials. Thus, the main contribution intended for the present study is to propose an efficient and accurate iterative enriched Ritz basis to deal with aeroviscoelastic systems. 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The flutter boundary prediction of complex aeroelastic systems is not an easy task. In some cases, these analyses may become prohibitive due to the high computational cost and time associated with the large number of degrees of freedom of the aeroelastic models, particularly when the aeroelastic model incorporates a control strategy with the aim of suppressing the flutter phenomenon, such as the use of viscoelastic treatments. In this situation, the use of a model reduction method is essential. However, the construction of a modal reduction basis for aeroviscoelastic systems is still a challenge, owing to the inherent frequency- and temperature-dependent behavior of the viscoelastic materials. Thus, the main contribution intended for the present study is to propose an efficient and accurate iterative enriched Ritz basis to deal with aeroviscoelastic systems. 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The flutter boundary prediction of complex aeroelastic systems is not an easy task. In some cases, these analyses may become prohibitive due to the high computational cost and time associated with the large number of degrees of freedom of the aeroelastic models, particularly when the aeroelastic model incorporates a control strategy with the aim of suppressing the flutter phenomenon, such as the use of viscoelastic treatments. In this situation, the use of a model reduction method is essential. However, the construction of a modal reduction basis for aeroviscoelastic systems is still a challenge, owing to the inherent frequency- and temperature-dependent behavior of the viscoelastic materials. Thus, the main contribution intended for the present study is to propose an efficient and accurate iterative enriched Ritz basis to deal with aeroviscoelastic systems. 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subjects	Aeroelasticity Aeronautics Cost analysis Efficiency Finite element Flutter analysis Flutter suppression Iterative methods Mathematical models Model reduction Panel flutter Passive control Predictions Reduction methods Supersonic aircraft Supersonic flow Temperature Temperature dependence Vibration Viscoelastic materials Viscoelasticity
title	An efficient iterative model reduction method for aeroviscoelastic panel flutter analysis in the supersonic regime
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