Numerical and Experimental Investigation of Wrinkling Pattern for Aerospace Laminated Membrane Structures

Hong, Yihong; Yao, Wenjuan; Xu, Yan

doi:10.1155/2017/8476041

Cited by 4 publications

(1 citation statement)

References 14 publications

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“…The present literature, however, was mainly concerned about the static behavior of a membrane, e.g. wrinkling patterns (Miyamura, 2000; Wong and Pellegrino, 2006a, 2006b, 2006c; Lecieux and Bouzidi, 2010; Atai and Steigmann, 2012, 2014; Taylor et al , 2014; Lan et al , 2014; Patil et al , 2015), wrinkling evolution (Wong and Pellegrino, 2006a, 2006b, 2006c; Wang et al , 2012, 2013a, 2013b) or transition (Davidovitch et al , 2011; Taylor et al , 2015), wrinkling location (Atai and Steigmann, 2012, 2014; Wang et al , 2014), stress distribution (Li et al , 2012; Huang et al , 2015; Senda et al , 2015), wrinkling critical load (Li, 2008; Wang et al , 2013b), post-wrinkling bearing capacity (Deng and Pellegrino, 2012; Hong et al , 2017), optimum design to eliminate wrinkles (Li et al , 2017; Liu et al , 2017; Luo et al , 2017), etc. A limited number of documents investigated the dynamic properties or dynamic responses of a membrane when its constitutive relationship was elastic (Hasheminejad et al , 2011; DasGupta and Tamadapu, 2013), orthotropic (Liu et al , 2013a, 2013b, 2016), hyperelastic (Soares and Gonçalves, 2012; Chaudhuri and DasGupta, 2014) or viscoelastic (Katsikadelis, 2012), or when it was subjected to impact loads (Liu et al , 2016), axial movement (Shin et al , 2005, 2006) or dynamic extension (Tuzela and Erbay, 2004).…”

Section: Introductionmentioning

confidence: 99%

Numerical analysis of dynamic properties of wrinkled thin membranes

Chu

Yang

2020

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Purpose This paper aims to numerically study the effects of boundary conditions, pre-stress, material constants and thickness on the dynamic performance of a wrinkled thin membrane. Design/methodology/approach Based on the stability theory of plates and shells, the dynamic equations of a wrinkled thin membrane were developed, and they were solved with the Lanczos method Findings The effects of wrinkle-influencing factors on the dynamic performance of a wrinkled membrane are determined by the wrinkling stage. The effects are prominent when wrinkling deformation is evolving, but they are very small and can hardly be observed when wrinkling deformation is stable. Mode shapes of a wrinkled membrane are sensitive to boundary conditions, pre-stress and Poisson’s ratio, but its natural frequencies are sensitive to all these five factors. Practical implications The research work in this paper is expected to help understand the dynamic behavior of a wrinkled membrane and present access to ensuring its dynamic stability by controlling the wrinkle-influencing factors. Originality/value Very few documents investigated the dynamic properties of wrinkled membranes. No attention has yet been paid by the present literature to the global dynamic performance of a wrinkled membrane under the influences of the factors that play a pivotal role in the wrinkling deformation. In view of this, this paper numerically studied the global modes and corresponding frequencies of a wrinkled membrane and their variation with the wrinkle-influencing factors. The results indicate that the global dynamic properties of a wrinkled membrane are sensitive to these factors at the stage of wrinkling evolution.

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