Publication:
Mathematical modeling and finite element computation of cosserat elastic plates

dc.contributor.advisor Steinberg, Lev
dc.contributor.author Kvasov, Roman
dc.contributor.college College of Engineering en_US
dc.contributor.committee Acar, Robert
dc.contributor.committee Castillo, Paul
dc.contributor.committee Just, Frederick
dc.contributor.department Department of Electrical and Computer Engineering en_US
dc.contributor.representative Cabrera Rios, Mauricio
dc.date.accessioned 2019-02-12T15:30:47Z
dc.date.available 2019-02-12T15:30:47Z
dc.date.issued 2013
dc.description.abstract In this dissertation the mathematical modeling of Cosserat elastic plates and their Finite Element computation are presented. The mathematical model for bending of Cosserat elastic plates, which assumes physically and mathematically motivated approximations over the plate thickness for stress, couple stress, displacement, and microrotation is developed. The approximations are consistent with the three dimensional Cosserat elasticity equilibrium equations, boundary conditions and the constitutive relationships. The Generalized Hellinger-Prange-Reissner Principle allows to obtain the equilibrium equations, constitutive relations and optimal value for the minimization of the elastic energy with respect to the splitting parameter. On of the main contributions of this dissertation is the comparison of the maximum vertical deflection for simply supported square plate with the analytical solution of the three-dimensional Cosserat elasticity. It confirms the high order of approximation of the three-dimensional (exact) solution. The computations produce a relative error of the order 1% in comparison with the exact three-dimensional solution that is stable with respect to the standard range of the plate thickness. The results are compatible with the precision of the well-known Reissner model used for bending of simple elastic plates. For the Finite Element formulation, the Cosserat plate field equations are presented as an elliptic system of nine differential equations in terms of the kinematic variables. The system includes an optimal value of the splitting parameter, which is the minimizer of the Cosserat plate stress energy. The Finite Element Method for Cosserat elastic plates based on the efficient numerical algorithm for the calculation of the optimal value of the splitting parameter and the computation of the corresponding unique solution of the weak problem is proposed. The numerical validation of the Finite Element Method shows its convergence to the analytical solution with optimal linear rate of convergence in H1-norm. The Finite Element computation of bending of clamped Cosserat elastic plates of arbitrary shapes under different loads is provided. The numerical results are obtained for the elastic plates made of dense polyurethane foam used in structural. en_US
dc.description.graduationSemester Spring en_US
dc.description.graduationYear 2013 en_US
dc.identifier.uri https://hdl.handle.net/20.500.11801/1797
dc.language.iso English en_US
dc.rights.holder (c) 2013 Roman Kvasov en_US
dc.rights.license All rights reserved en_US
dc.subject Mathematical modeling en_US
dc.subject Cosserat elastic plates en_US
dc.title Mathematical modeling and finite element computation of cosserat elastic plates en_US
dc.type Dissertation en_US
dspace.entity.type Publication
thesis.degree.discipline Computing and Information Sciences and Engineering en_US
thesis.degree.level Ph.D. en_US
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