Detail publikace
Numerical estimation of the macroscopic stress-strain curve of a particulate composite with crosslinked polymer matrix
NÁHLÍK, L. HUTAŘ, P. DUŠKOVÁ, M. DUŠEK, K. MÁŠA, B.
Originální název
Numerical estimation of the macroscopic stress-strain curve of a particulate composite with crosslinked polymer matrix
Typ
článek v časopise - ostatní, Jost
Jazyk
angličtina
Originální abstrakt
The main focus of a present paper is an estimation of the macroscopic stress-strain behavior of a particulate composite. The particulate composite with a crosslinked polymer matrix in a rubbery state filled by an alumina-based mineral filler is investigated by means of the finite element method. A hyperelastic material behavior of the matrix is modeled by the Mooney-Rivlin material model. Numerical models on the basis of unit cells are developed. An assumption of the existence of the discontinuity (breaking) in the matrix at higher loading levels is taken into account to obtain a more accurate estimation of the stress-strain behavior of the particulate composite investigated. The numerical results obtained are compared with experimental stress-strain curve and good agreement has been found. The paper can contribute to a better understanding of the behavior and failure of particulate composites with a polymer matrix.
Klíčová slova
particulate composites, polymer-matrix composites, mechanical response, finite-element analysis
Autoři
NÁHLÍK, L.; HUTAŘ, P.; DUŠKOVÁ, M.; DUŠEK, K.; MÁŠA, B.
Rok RIV
2012
Vydáno
9. 1. 2012
ISSN
0191-5665
Periodikum
MECHANICS OF COMPOSITE MATERIALS
Ročník
47
Číslo
6
Stát
Spojené státy americké
Strany od
627
Strany do
634
Strany počet
8
BibTex
@article{BUT90659,
author="Luboš {Náhlík} and Pavel {Hutař} and Miroslava {Dušková} and Karel {Dušek} and Bohuslav {Máša}",
title="Numerical estimation of the macroscopic stress-strain curve of a particulate composite with crosslinked polymer matrix",
journal="MECHANICS OF COMPOSITE MATERIALS",
year="2012",
volume="47",
number="6",
pages="627--634",
issn="0191-5665"
}