In this dissertation, the finite deformations of a certain class of compressible,
isotropic elastic materials are investigated. The class is characterized by a two-parameter
family of strain energy functions which includes the well-known Blatz-Ko material
model for foam rubbers. The Blatz-Ko material, which has been arrived at by
experiment and whose deformations have been studied previously, is obtained from
the considered class of materials by specifying one of the two parameters involved in
the definition of the class. On employing the semi-inverse method, according to which
the form of the solution is given at the outset in terms of functions which are then
determined from the equilibrium equations and boundary conditions, closed-form solutions
to the equilibrium equations are obtained for the non-homogeneous deformations
describing the straightening of a sector of a circular tube, the bending of a rectangular
block into a sector of a circular tube, the eversion of cylindrical and spherical shells,
and the cylindrical and spherical expansions, and a number of associated boundary
value problems are investigated using both analytical and numerical methods. Certain
situations in which solutions of the pre-assigned form cannot exist are identified and
cases of non-uniqueness are dealt with by discriminating between the different solutions
on physical grounds. The homogeneous deformations of the materials in this class are
also examined and, throughout, comparison is being made with the behaviour of the
Blatz-Ko material. For the whole range of deformations examined, it is found that
the materials for which one of the parameters is greater than, or equal to, two (the
case when this parameter equals to two corresponds to the Blatz-Ko material) become
harder as this parameter increases, but that otherwise they all behave in a similar
manner. Consequently, it is concluded that the materials in this particular subclass
will also represent foam rubbers of the type described by the Blatz-Ko material. In
order to describe the situations in which the solutions become unstable, the conditions
for the strong ellipticity of the equilibrium equations for non-linearly elastic materials
are reformulated so as to be expressible in terms of the derivatives of the strain-energy
function regarded as a function of the principal stretches. Use of these conditions reveals
that the solutions to the considered boundary value problems become unstable
at certain critical values of the applied loads.
Date of Award | 1996 |
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Original language | English |
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Awarding Institution | |
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FINITE DEFORMATIONS OF A GENERALIZED BLATZ-KO MATERIAL
WANG, Y. (Author). 1996
Student thesis: PhD