Nodeless variable finite element method for heat transfer analysis by means of flux-based formulation and mesh adaptation

Based on flux-based formulation, a nodeless variable element method is developed to analyze two-dimensional steady-state and transient heat transfer problems. The nodeless variable element employs quadratic interpolation functions to provide higher solution accuracy without necessity to actually gen...

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Bibliographic Details
Published in:Acta mechanica Sinica 2006-04, Vol.22 (2), p.138-147
Main Authors: Phongthanapanich, Sutthisak, Traivivatana, Suthee, Boonmaruth, Parinya, Dechaumphai, Pramote
Format: Article
Language:English
Subjects:
Accuracy
Computing time
Conduction heating
Conductive heat transfer
Exact solutions
Finite element analysis
Finite element method
Heat transfer
Interpolation
Mesh generation
Square plates
Steady state
Transient heat conduction
Transient heat transfer
Two dimensional analysis
变量元
有限元法
流量表述
热传递
稳定态
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Summary:Based on flux-based formulation, a nodeless variable element method is developed to analyze two-dimensional steady-state and transient heat transfer problems. The nodeless variable element employs quadratic interpolation functions to provide higher solution accuracy without necessity to actually generate additional nodes. The flux-based formulation is applied to reduce the complexity in deriving the finite element equations as compared to the conventional finite element method, The solution accuracy is further improved by implementing an adaptive meshing technique to generaie finite element mesh that can adapt and move along corresponding to the solution behavior. The technique generates small elements in the regions of steep solution gradients to provide accurate solution, and meanwhile it generates larger elements in the other regions where the solution gradients are slight to reduce the computational time and the computer memory. The effectiveness of the combined procedure is demonstrated by heat transfer problems that have exact solutions. These problems tire: (a) a steady-state heat conduction analysis in a square plate subjected to a highly localized surface heating, and (b) a transient heat conduction analysis in a long plate subjected to moving heat source.
ISSN:0567-7718
1614-3116
DOI:10.1007/s10409-006-0097-3