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 AJCM  Vol.5 No.2 , June 2015
Theories and Analyses Thick Hyperbolic Paraboloidal Composite Shells
Abstract: This paper presents the stress resultants of hyperbolic paraboloidal shells using higher order shear deformation theory recently developed by Zannon [1]-[3]. The equilibrium equations of motion use Hamilton’s minimum energy principle for a simply supported cross-ply structure by Zannon (TSDTZ) [2] [3]. The results are calculated for orthotropic, two-ply unsymmetrical [90/0] shells. The extensional, bending and coupling stiffness parameters are calculated using MATLAB algorithm for laminated composite hyperbolic paraboloidal shells. A comparison of the present study with other researchers in the literature is given, and is in good agreement.
Cite this paper: Zannon, M. , Al-Shutnawi, B. and Alrabaiah, H. (2015) Theories and Analyses Thick Hyperbolic Paraboloidal Composite Shells. American Journal of Computational Mathematics, 5, 80-85. doi: 10.4236/ajcm.2015.52006.
References

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http://dx.doi.org/10.4271/2013-01-1989

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