Title of article
Uncertainties propagation in metamodel-based probabilistic optimization of CNT/polymer composite structure using stochastic multi-scale modeling
Author/Authors
Ghasemi، نويسنده , , Hamid and Rafiee، نويسنده , , Roham and Zhuang، نويسنده , , Xiaoying and Muthu، نويسنده , , Jacob and Rabczuk، نويسنده , , Timon، نويسنده ,
Issue Information
روزنامه با شماره پیاپی سال 2014
Pages
11
From page
295
To page
305
Abstract
This research focuses on the uncertainties propagation and their effects on reliability of polymeric nanocomposite (PNC) continuum structures, in the framework of the combined geometry and material optimization. Presented model considers material, structural and modeling uncertainties. The material model covers uncertainties at different length scales (from nano-, micro-, meso- to macro-scale) via a stochastic approach. It considers the length, waviness, agglomeration, orientation and dispersion (all as random variables) of Carbon Nano Tubes (CNTs) within the polymer matrix. To increase the computational efficiency, the expensive-to-evaluate stochastic multi-scale material model has been surrogated by a kriging metamodel. This metamodel-based probabilistic optimization has been adopted in order to find the optimum value of the CNT content as well as the optimum geometry of the component as the objective function while the implicit finite element based design constraint is approximated by the first order reliability method. Uncertain input parameters in our model are the CNT waviness, agglomeration, applied load and FE discretization. Illustrative examples are provided to demonstrate the effectiveness and applicability of the present approach.
Keywords
CNT/polymer composite , reliability analysis , Reliability Based Design Optimization (RBDO) , Carbon Nano Tube (CNT) , Multi-Scale Modeling
Journal title
Computational Materials Science
Serial Year
2014
Journal title
Computational Materials Science
Record number
1692593
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