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Experimental and numerical assessment of the equivalent-orthotropic-thin-plate model for bending of corrugated panels

: Aoki, Yohko; Maysenhölder, Waldemar

Fulltext urn:nbn:de:0011-n-4350562 (3.3 MByte PDF)
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Created on: 14.3.2017

International Journal of Solids and Structures 108 (2017), pp.11-23
ISSN: 0020-7683
Journal Article, Electronic Publication
Fraunhofer IBP ()

Numerous papers deal with the Equivalent Plate Model (EPM) for corrugated panels. Comparison of published formulas for the four relevant equivalent bending stiffnesses D11 eq, D22 eq, D66 eq, andD12 eq revealed ambiguities: Three different formulas were found for D22 eq, which describes the bending of the ridges and troughs; for D66 eq two âcompetingâ formulas emerged. Expressions not converging to the flat-plate values in the limit of vanishing corrugation height were discarded. All discussed formulas are written in a uniform notation for general one-dimensionally periodic shapes. Formulas derived for isotropic panel materials were generalized to the orthotropic case. In order to resolve the ambiguities and assess the EPM with regard to its range of applicability, vibration modes of six rectangular corrugated panels were measured. While agreement with numerical results obtained with COMSOL was fair, the EPM predictions of natural frequencies were satisfactory only for low-order modes. Finally, equivalent bending stiffnesses were determined numerically from COMSOL results for a few low-order modes by inverse methods. Thus the ambiguities with regard to D22 eq and D66 eq could be resolved. However, the D12 eq values determined numerically came out significantly larger than the EPM prediction, in particular for stronger corrugations. Even though this discrepancy had little effect on the natural frequencies tested in the present paper, it remains a theoretical challenge.