Open AccessStability of the Shallow Axisymmetric Parabolic-Conic Bimetallic Shell by Nonlinear Theory
Author(s) -
M. Jakomin,
F. Kosel
Publication year - 2011
Publication title -
mathematical problems in engineering
Language(s) - English
Resource type - Journals
SCImago Journal Rank - 0.262
H-Index - 62
eISSN - 1026-7077
pISSN - 1024-123X
DOI - 10.1155/2011/145638
Subject(s) - thermoelastic damping , conic section , rotational symmetry , nonlinear system , shell (structure) , deformation (meteorology) , mechanics , mathematical analysis , stress (linguistics) , mathematics , geometry , classical mechanics , thermal , materials science , physics , thermodynamics , composite material , linguistics , philosophy , quantum mechanics
In this contribution, we discuss the stress, deformation, and snap-through conditions of thin, axi-symmetric, shallow bimetallic shells of so-called parabolic-conic and plate-parabolic type shells loaded by thermal loading. According to the theory of the third order that takes into account the balance of forces on a deformed body, we present a model with a mathematical description of the system geometry, displacements, stress, and thermoelastic deformations. The equations are based on the large displacements theory. We numerically calculate the deformation curve and the snap-through temperature using the fourth-order Runge-Kutta method and a nonlinear shooting method. We show how the temperature of both snap-through depends on the point where one type of the rotational curve transforms into another
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