Multiscale modeling of microstructural and hygrothermal effects on vibrations of CNT-enhanced fiber-reinforced polymer composites

•Multiscale model for hygrothermomechanical vibrations in CNT-enhanced composites.•Analytical methods incorporate CNT orientation, waviness, and agglomeration effects.•Enhanced vibration response validated by FEM and experimental results.•Examines microstructural effects of CNTs on composite vibrati...

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Bibliographic Details
Published in:Journal of sound and vibration 2025-02, Vol.596, p.118733, Article 118733
Main Authors: Antoniou, Panagiotis A., Markolefas, Stylianos I., Giannopoulos, Georgios I., Lagaros, Nikolaos, Georgantzinos, Stelios K.
Format: Article
Language:English
Subjects:
Agglomeration
Finite element method
Hygro-thermal stresses
Laminated composites
MWCNTs
Vibration analysis
Waviness
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Summary:•Multiscale model for hygrothermomechanical vibrations in CNT-enhanced composites.•Analytical methods incorporate CNT orientation, waviness, and agglomeration effects.•Enhanced vibration response validated by FEM and experimental results.•Examines microstructural effects of CNTs on composite vibrations.•Design insights for CNT-reinforced composites under environmental conditions. This work presents a multi-scale analytical and computational approach designed to predict the hygro-thermo-mechanical vibrational response of laminated composite structures reinforced with multi-walled carbon nanotubes (MWCNTs). Employing the modified Halpin-Tsai model, this study estimates the elastic properties of the MWCNT-enhanced epoxy matrix, incorporating the impacts of MWCNT agglomeration, orientation, waviness, and size-dependent characteristics. Additionally, the Chamis micromechanical model is utilized to ascertain the independent elastic constants of the nanocomposite lamina, considering environmental variables such as temperature and humidity. Subsequent analysis involves the determination of natural frequencies for both pristine and MWCNT-integrated laminated composite structures via the Finite Element Method (FEM), addressing various design-related parameters. This investigation further explores the macroscopic influences of MWCNT incorporation, boundary condition and layup scheme, along with the temperature, moisture content, and the nanoscopic impact of MWCNTs on the natural frequencies of laminated composite plates. The obtained results of the proposed multiscale modeling are compared with experimental and theoretical observations. It has been demonstrated that while the incorporation of carbon nanotubes (CNTs) can enhance the mechanical properties of nanocomposite laminae, the natural frequencies of these nanocomposite plates are adversely affected by variations in temperature and moisture content. Furthermore, the findings indicate that the microstructural characteristics of CNTs play a crucial role in determining the efficacy of the reinforcement phenomenon. The developed multi-scale methodological framework offers significant potential for the design and optimization of MWCNT-based composite structures across diverse industries, including automotive and aerospace sectors.
ISSN:0022-460X
DOI:10.1016/j.jsv.2024.118733