The Direct Boundary Element Method Applied to Modeling Differential and Integral Elastic Thin and Thick Plates Equations
Resumo
Differential and integral elastic plates equations are frequently performed using
numerical methods like the Finite Element Method (FEM) or the Boundary Element
Method (BEM). One of the main differences between these techniques is a direct treatment
of boundary value problem in BEM analysis. It must be pointed out that corner forces are
introduced in the direct boundary integral equation when polygonal plates are studied using
classical theory. This parameter appears as a consequence of classical plate hypothesis in
which curvatures are related with the second derivative of the out-of-plane displacement and
it is the necessary condition to reduce boundary variables. However, when thick plate theory
is considered curvatures are not directly related with out-of-plane displacement derivative
and no corner forces are introduced even in BEM analysis. Further, three boundary
conditions should be satisfied in thick plate analysis rather than two of classical theory. This
study intends to present results obtained from plate bending problems using classical and
thick plate theories in order to understand the differences in plate behavior due the features
above mentioned. The classical plate analysis will be performed using Dansons
fundamental solutions and Reissner theory will be used in thick plates analysis with
Weeëns fundamental solution. The numerical implementation is carried out for continuous
or discontinuous isoparametric linear elements. A classical example is solved to show the
aim of this paper and the results are compared with those available in the literature.