Probing the prediction of effective properties for composite materials

This article presents different micromechanical modelling techniques based on analytical and numerical approaches to determine the effective elastic and piezoelectric (piezoelastic) properties of graphene-based composite materials. Different types, orientations and shapes as well as different geomet...

Full description

Saved in:
Bibliographic Details
Published in:European journal of mechanics, A, Solids A, Solids, 2021-05, Vol.87, p.104228, Article 104228
Main Authors: Shingare, K.B., Naskar, S.
Format: Article
Language:English
Subjects:
Composite materials
Covalent bonds
Elastic properties
Fiber reinforcement
Finite element (FE) methods
Graphene
Homogenization
Material properties
Micromechanical models
Parameters
Piezoelectric materials
Piezoelectricity
Representative volume element
Robustness (mathematics)
Citations: Items that this one cites
Items that cite this one
Online Access:Get full text
Tags: Add Tag
No Tags, Be the first to tag this record!
Description
Summary:This article presents different micromechanical modelling techniques based on analytical and numerical approaches to determine the effective elastic and piezoelectric (piezoelastic) properties of graphene-based composite materials. Different types, orientations and shapes as well as different geometrical parameters of fiber reinforcement are considered for estimating the effective properties. The effective properties of composite are predicted with and without considering the strong covalent bond which provides interaction and in-plane stability of 2Dcrystalline graphene or strong van der Wall forces formed between graphene layers and the matrix. It is revealed that the axial, transverse and shear effective piezoelastic properties of graphene reinforced piezoelectric composite (GRPC) are significantly enriched due to the incorporation of graphene into the epoxy matrix. The importance of incorporating graphene as nanofillers/interphase into the conventional epoxy matrix to form an advanced composite and its effective properties are illustrated while these results show excellent agreement with previously reported experimental estimates. These results reveal that due to incorporation of graphene nanofillers, there is a significant enhancement in effective properties of composite. The results would also help to recognize the most important material properties with respect to different shapes and orientation of reinforcements which influences the performance of system significantly. To confirm safety, robustness and sustainability of the structure, it is the most prior requirement to determine the effective properties of composites considering different parameters for the different static and structural analyses. •The micromechanical models are proposed to predict the effective properties of graphene-based piezoelectric composite.•In this, the different types, orientations, shapes and geometrical parameters of fiber reinforcement are considered.•The strong covalent bond and van der Wall forces in graphene offers interaction and in-plane stability in composite.•It is revealed that the effective properties are significantly enriched due to incorporation of graphene into matrix.•The current study helps to recognize the properties of graphene-based composite which improves the performance of system.
ISSN:0997-7538
1873-7285
DOI:10.1016/j.euromechsol.2021.104228