FINITE ELEMENT SIMULATION OF THREE-DIMENSIONAL TURBULENT FLOW WITH DECAYING SWIRL

A finite element based numerical model is employed to obtain isothermal and heat transfer predictions for the case of turbulent flow with a decaying swirl component in a stationary circular pipe. An assessment is made on the quality of predictions based on the choice of turbulence modelling techniqu...

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Bibliographic Details
Published in:International journal of numerical methods for heat & fluid flow 1993-06, Vol.3 (6), p.545-564
Main Authors: CASEY, M.R, KONG, L, TAYLOR, C, MEDWELL, J.O
Format: Article
Language:English
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Summary:A finite element based numerical model is employed to obtain isothermal and heat transfer predictions for the case of turbulent flow with a decaying swirl component in a stationary circular pipe. An assessment is made on the quality of predictions based on the choice of turbulence modelling technique adopted to close the governing equations. In the present work the one-equation, two-equation and algebraic Reynolds stress turbulence models are employed. For the confined flow problem investigated, accurate prediction of the near-wall conditions is essential. This is particularly the case for confined swirling flow where the variation of variables near the wall is often somewhat greater than encountered in pure axial flow. A finite element based near-wall model is employed as an alternative to conventional techniques such as the use of the standard logarithmic functions. Of significance is the fact that flow predictions based on the use of the unidimensional finite element techniques are closer to experiment compared to the wall function based solutions for a given turbulence model. As expected, improvements in the flow predictions directly contribute to improved simulation of the thermal aspects of the problem.
ISSN:0961-5539
1758-6585
DOI:10.1108/eb017547