Elastic finite element analysis on cross-sections of random hollow sphere structures

Fiedler, T.; Kim, H. S.; Belova, I. V.; Sloan, S. W.; Murch, G. E.; Öchsner, A.

Title: Elastic finite element analysis on cross-sections of random hollow sphere structures
Creator: Fiedler, T.; Kim, H. S.; Belova, I. V.; Sloan, S. W.; Murch, G. E.; Öchsner, A.
Relation: Materialwissenschaft und Werkstofftechnik Vol. 41, Issue 5, p. 250-256
Publisher Link: http://dx.doi.org/10.1002/mawe.201000593
Publisher: Wiley - VCH Verlag GmbH & Co. KGaA
Resource Type: journal article
Date: 2010
Description: This paper addresses elastic analysis based on 2D finite element models for metallic hollowsphere structures. In the first part, the influence of micro-porosity on the elastic behaviour of sintered metallic hollow sphere wall material is investigated. Young's modulus of the metallic hollow sphere wall material is found to linearly decrease with increasing micro-porosity ranging up to about 45%. In the second part, elastic parameters for metallic syntactic foams (MSF) consisting of thin or thick walled hollow spheres, and for epoxy containing spherical pores are studied. Data obtained from finite element models are compared with theoretical predictions based on the rule of mixtures developed elsewhere and found to be in good agreement with each other for MSF but not for porous epoxy. The shear modulus of MSF with thin-walled hollow spheres was found to increase with increasing volume fraction of matrix whereas that of MSF with thick walled hollow spheres was found to decrease. Specific Young's modulus of MSF with thin-walled hollow spheres was also found to increase with increasing foam density whereas that of MSF with thick walled hollow spheres was found to decrease. Poisson's ratio obtained was relatively low for porous epoxy matrix material but high for MSF with thin or thick-walled hollow spheres.
Subject: finite element analysis; cellular metal; hollow spheres; syntactic foam; elastic properties
Identifier: http://hdl.handle.net/1959.13/921756
Identifier: uon:9392
Identifier: ISSN:0933-5137
Language: eng
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