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A NEW FINITE ELEMENT FORMULATION FOR PLANAR ELASTIC DEFORMATION

โœ Scribed by ZHIMING YE

Publisher
John Wiley and Sons
Year
1997
Tongue
English
Weight
392 KB
Volume
40
Category
Article
ISSN
0029-5981

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โœฆ Synopsis

For the stress analysis of planar deformable bodies, we usually refer to either plane stress or plane strain hypothesis. Three-dimensional analysis is required when neither hypothesis is applicable, e.g. bodies with finite thickness. In this paper, we derive an 'exact' solution for the plane stress problem based on a less restrictive hypothesis than X "0. By requiring the out-plane stress X to be a harmonic function, the three-dimensional solution is obtained. In addition, we present a two-dimensional finite element for planar analysis of problems where the thickness of the body 2h is comparable to other characteristic dimensions. This element is presented as a substitute for classical plane stress and plane strain finite elements. The typical plane stress and plane strain state are recovered in the case where hP0 and the case hPR, respectively. As an example for the application of such formulation, the behaviour of a concrete gravity dam is investigated. It is shown that this structure, typically analysed by using plane strain hypothesis, has its out-plane stress underestimated.

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