Sub-modelling and boundary conditions with p -type hybrid-equilibrium plate-membrane elements
The main topics of this paper, sub-modelling and associated boundary conditions, are presented in two parts. The first part details a general method for evaluating consistent displacement or traction modes for hybrid equilibrium plate models to represent arbitrarily specified boundary conditions. Th...
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Veröffentlicht in: | Finite elements in analysis and design 2006-12, Vol.43 (2), p.155-167 |
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Format: | Artikel |
Sprache: | eng |
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Zusammenfassung: | The main topics of this paper, sub-modelling and associated boundary conditions, are presented in two parts. The first part details a general method for evaluating consistent displacement or traction modes for hybrid equilibrium plate models to represent arbitrarily specified boundary conditions. The inheritance of boundary conditions in a process of uniform
h-type refinement is considered as a particular case. The second part investigates the methodology and performance of a sub-modelling technique involving equilibrium elements, which has the aim of recovering a local quantity of interest with greater accuracy than that directly obtained from the original global or parent equilibrium model. A crucial step in this technique is the transfer of appropriate boundary tractions from the parent model to the sub-model (child). The sub-modelling technique is presented initially based on the extraction of a single element for
h- and/or
p-type refinement into sub-models. A more general form of sub-modelling is then presented in which the boundary of the sub-model does not coincide with that of an element, or patch of elements, in the parent model. This requires the evaluation of modes of traction around an arbitrary region, and a scheme to achieve this is presented and demonstrated using, as an example, a geometric perturbation of a single element extraction. The performances of sub-models are compared using both complete sets of traction modes and reduced, or basic, sets. |
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ISSN: | 0168-874X 1872-6925 |
DOI: | 10.1016/j.finel.2006.08.002 |