Micromechanical modeling and characterization of elastic behavior of carbon nanotube‐reinforced polymer nanocomposites: A combined numerical approach and experimental verification

In this study, a combined analytical and finite element‐based micromechanical modeling is performed to characterize the elastic properties of carbon nanotube (CNT) reinforced polymer nanocomposites and validated with experimental work. First, coordinates of armchair and zigzag type CNTs are generate...

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Bibliographic Details
Published in:Polymer composites 2020-08, Vol.41 (8), p.3322-3339
Main Authors: Kassa, Mesfin Kebede, Arumugam, Ananda Babu
Format: Article
Language:English
Subjects:
Boundary conditions
CAD
Chirality
CNT
Computer aided design
Computer simulation
Elastic analysis
Elastic properties
Equivalence
experimentation
FEM
Finite element method
Mathematical analysis
Mathematical models
micromechanics
Modulus of elasticity
Nanocomposites
Polymers
Single wall carbon nanotubes
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Summary:In this study, a combined analytical and finite element‐based micromechanical modeling is performed to characterize the elastic properties of carbon nanotube (CNT) reinforced polymer nanocomposites and validated with experimental work. First, coordinates of armchair and zigzag type CNTs are generated using MATLAB based on the geometric structure of the CNTs and imported to the computational software ANSYS to model and characterize the elastic properties of the individual single‐walled CNT (SWCNT) and multi‐walled CNT by applying various loading and boundary conditions. The present developed finite element method (FEM) model of CNTs is validated with the available literature in terms of elastic properties. Subsequently, the equivalent elastic properties of CNT reinforced epoxy nanocomposites are determined through representative volume element (RVE) model by finite element simulations and Mori‐Tanaka homogenization techniques by replacing CNTs with equivalent fibers as microinclusions. The equivalent elastic properties of nanocomposite obtained by the FEM and analytical model are compared and validated with the experimental results. Further, the detailed parametric study is performed to investigate the influence of tube chirality, volume fraction, and orientation of CNT in terms of the elastic properties of the nanocomposite. It was observed that the armchair type CNT reinforced nanocomposites are stiffer than the zigzag type SWCNT reinforced nanocomposites in terms of elastic moduli. Further, it was noticed that the tube chirality and the number of walls of CNTs have significantly influenced the elastic behavior of nanocomposites. It can be concluded that the presented combined model provides an efficient methodology and comprehensive understanding to analyze the elastic behavior of CNTs and CNT reinforced nanocomposites. So, the presented combined numerical and experimental study could serve as a guideline in micromechanical modeling and characterization of elastic behavior of CNT‐reinforced polymer nanocomposites. In this study, a combined analytical and finite element based micromechanical modeling is performed to characterize the elastic properties of carbon nanotube reinforced polymer nanocomposites and validated with experimental work. The equivalent elastic properties of nanocomposite obtained by the finite element method and analytical model are compared and validated with the experimental results obtained.
ISSN:0272-8397
1548-0569
DOI:10.1002/pc.25622