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Large-eddy simulation of the turbulent flow through a heated square duct
Large-eddy simulations of a compressible turbulent square duct flow at low Mach number are described. First, we consider the isothermal case with all the walls at the same temperature: good agreement with previous incompressible DNS and LES results is obtained both for the statistical quantities and...
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Published in: | Journal of fluid mechanics 2002-02, Vol.453, p.201-238 |
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Main Authors: | , |
Format: | Article |
Language: | English |
Subjects: | |
Citations: | Items that cite this one |
Online Access: | Get full text |
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Summary: | Large-eddy simulations of a compressible turbulent square duct flow at low Mach
number are described. First, we consider the isothermal case with all the walls at
the same temperature: good agreement with previous incompressible DNS and LES
results is obtained both for the statistical quantities and for the turbulent structures.
A heated duct with a higher temperature prescribed at one wall is then considered
and the intensity of the heating is varied widely. The increase of the viscosity with
temperature in the vicinity of the heated wall turns out to play a major rôle. We
observe an amplification of the near-wall secondary flows, a decrease of the turbulent
fluctuations in the near-wall region and, conversely, their enhancement in the outer
wall region. The increase of the viscous thickness with heating implies a significant
augmentation of the size of the characteristic flow structures such as the low- and
high-speed streaks, the ejections and the quasi-longitudinal vorticity structures. For
strong enough heating, the size limitation imposed by the lateral walls leads to a single
low-speed streak located near the duct central plane surrounded by two high-speed
streaks on both sides. Violent ejections of slow and hot fluid from the heated wall are
observed, linked with the central low-speed streak. A selective statistical sampling of
the most violent ejection events reveals that the entrainment of cold fluid, originated
from the duct core, at the base of the ejection and its subsequent expansion amplifies
the ejection intensity. |
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ISSN: | 0022-1120 1469-7645 |
DOI: | 10.1017/S0022112001006887 |