A comprehensive multi-scale analytical modelling framework for predicting the mechanical properties of strand-based composites

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• 作者：Sardar Malekmohammadi (1) (4)
  Navid Zobeiry (1)
  Thomas Gereke (2)
  Benjamin Tressou (3)
  Reza Vaziri (1)
  
  1. Composites Group ; Departments of Civil Engineering and Materials Engineering ; The University of British Columbia ; 6250 Applied Science Lane ; Vancouver ; BC ; V6T1Z4 ; Canada
  4. Department of Materials Science and Engineering ; Massachusetts Institute of Technology ; 77 Massachusetts Ave ; Cambridge ; MA ; 02139 ; USA
  2. Institute of Textile Machinery and High Performance Material Technology ; Technische Universit盲t Dresden ; 01062 ; Dresden ; Germany
  3. D茅partement Physique et M茅canique des Mat茅riaux ; Institut P鈥? ENSMA - UPR 3346 ; CNRS - Universit茅 de Poitiers ; 1 ; Avenue Cl茅ment Ader ; BP 40109 ; 86961 ; Futuroscope ; Chasseneuil Cedex ; France
  
• 刊名：Wood Science and Technology
• 出版年：2015
• 出版时间：January 2015
• 年：2015
• 卷：49
• 期：1
• 页码：59-81
• 全文大小：1,094 KB
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• 刊物类别：Biomedical and Life Sciences
• 刊物主题：Life Sciences
  Wood Science and Technology
  Ceramics,Glass,Composites,Natural Materials
  Operating Procedures and Materials Treatment
  
• 出版者：Springer Berlin / Heidelberg
• ISSN：1432-5225

文摘

A multi-scale modelling framework was developed for predicting the mechanical properties of strand-based wood composites. This framework is based on closed-form analytical models at three different resolution levels; micro-, meso- and macro-mechanical. A preprocessing step was performed to provide the input data for the three main modelling steps in this framework. Finite element-based mechanical analyses were employed to verify the accuracy of the analytical models developed for the first two steps. The predictive capability of the entire framework was validated using a set of experimental data reported in the literature. Although the methodology presented is general, it has specifically been applied here to predict an important structural property (modulus of elasticity, MOE) of a special strand-based wood composite product, namely, oriented strand board (OSB). The MOE predictions of OSB panels showed reasonable agreement with the available experimental data, thus providing confidence in the practical utility of this easy-to-use and efficient analytical modelling tool for predicting the properties of wood composites employed in structural members.