Article: Influence of particle arrangement on the stiffness and thermal expansion coefficient of aluminium-epoxy composites Journal: International Journal of Materials and Structural Integrity (IJMSI) 2016 Vol.10 No.4 pp.133 - 156 Abstract: The stiffness and thermal expansion coefficient of periodic polymer composites containing identical spherical particles are studied using micromechanics principles. A cubic unit cell has been considered to predict thermomechanical properties of particulate polymeric composites. This model takes into account the influence of the distribution (arrangement) of spherical inclusions on the thermomechanical constants of the composite material consisting of matrix and filler. A composite model derived from the cubic and face-centred cubic model representing the basic cell of the composite at a microscopic scale was transformed into a five-phase spherical representative volume element (which will be referred henceforth as R.V.E.), in order to apply the classical theory of elasticity to it. Theoretical values arising from this proposed model were compared with experimental results carried out with epoxy resin composites filled with aluminium particles and also with those obtained from other theoretical formulas derived by other scientists. Inderscience Publishers - linking academia, business and industry through research

Title: Influence of particle arrangement on the stiffness and thermal expansion coefficient of aluminium-epoxy composites

Authors: Emilio P. Sideridis; Evangelos K. Ioakeimidis; Victor N. Kytopoulos

Addresses: Section of Mechanics, Faculty of Applied Mathematics and Physical Sciences, N.T.U.A., Greece ' Faculty of Mineral and Metallurgical Eng., N.T.U.A., Greece ' Section of Mechanics, Laboratory of Strength and Materials, Faculty of Applied Mathematics and Physical Sciences, N.T.U.A., 5, Iroon Polytechniou Street, Zografou Campus, 15773 Athens, Greece

Abstract: The stiffness and thermal expansion coefficient of periodic polymer composites containing identical spherical particles are studied using micromechanics principles. A cubic unit cell has been considered to predict thermomechanical properties of particulate polymeric composites. This model takes into account the influence of the distribution (arrangement) of spherical inclusions on the thermomechanical constants of the composite material consisting of matrix and filler. A composite model derived from the cubic and face-centred cubic model representing the basic cell of the composite at a microscopic scale was transformed into a five-phase spherical representative volume element (which will be referred henceforth as R.V.E.), in order to apply the classical theory of elasticity to it. Theoretical values arising from this proposed model were compared with experimental results carried out with epoxy resin composites filled with aluminium particles and also with those obtained from other theoretical formulas derived by other scientists.

Keywords: aluminium particles; particle reinforced composites; filler volume fraction; representative volume element; elastic modulus; thermal expansion coefficient; particle distribution; stiffness; aluminium epoxy composites; periodic polymer composites; spherical particles; micromechanics; composite materials; elasticity.

DOI: 10.1504/IJMSI.2016.082126

International Journal of Materials and Structural Integrity, 2016 Vol.10 No.4, pp.133 - 156

Received: 29 Oct 2015
Accepted: 02 Nov 2016
Published online: 07 Feb 2017 *

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Title: Influence of particle arrangement on the stiffness and thermal expansion coefficient of aluminium-epoxy composites

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