Prediction of Mechanical Properties of Mica-filled Epoxy Composite Using Various Mechanical Models

Abstract

This paper reports an investigation on the prediction of tensile properties of mica-filled epoxy composites. Various mechanical models were used to predict the tensile properties of mica-filled epoxy composites at several mica concentrations (5-30 vol%). The tensile properties of mica-filled epoxy at various mica contents were determined experimentally and modeled using Nielsen, Nicolais-Narkis, Verbeek, Halpin-Tsai, Guth, and Novak models. It was found that the tensile modulus of epoxy increases with increasing mica content, whereas the elongation at break and tensile strength decrease. Predictions, which have been offered by the models on tensile strength, elongation at break, and Young’s modulus, are in good agreement with experimental data over the range of mica contents studied. The Halpin-Tsai model shows best agreement in predicting the Young’s modulus (accuracy > 93 %), and Novak curve fitting shows best prediction for elongation at break (accuracy > 99%) for mica-filled composites. In the case of tensile strength, good agreement with Nicolais-Narkis models (accuracy > 99%) was obtained.

Keywords

polymer matrix composites (PMCs)mechanical properties analytical modeling.

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