Influence of rheological parameters on polymer induced turbulent drag reduction

Direct numerical simulations (DNS) of polymer induced drag reduction in turbulent channel flows up to the maximum drag reduction (MDR) limit have been performed using a fully spectral method in conjunction with kinetic theory based elastic dumbbell models for the description of polymer chain dynamic...

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Veröffentlicht in:	Journal of non-Newtonian fluid mechanics 2006-12, Vol.140 (1), p.23-40
Hauptverfasser:	Li, Chang-Feng, Sureshkumar, Radhakrishna, Khomami, Bamin
Format:	Artikel
Sprache:	eng
Schlagworte:	Computational methods in fluid dynamics Dilute polymeric solutions Direct numerical simulation (DNS) Drag reduction Exact sciences and technology FENE-P model Flows in ducts, channels, nozzles, and conduits Fluid dynamics Fundamental areas of phenomenology (including applications) Oldroyd-B model Physics Spectral techniques Turbulence control Turbulent channel flows Turbulent flows, convection, and heat transfer
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container_title	Journal of non-Newtonian fluid mechanics
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creator	Li, Chang-Feng Sureshkumar, Radhakrishna Khomami, Bamin
description	Direct numerical simulations (DNS) of polymer induced drag reduction in turbulent channel flows up to the maximum drag reduction (MDR) limit have been performed using a fully spectral method in conjunction with kinetic theory based elastic dumbbell models for the description of polymer chain dynamics. It is shown that to obtain significant levels of drag reduction large polymer chain extensibility and high Weissenberg numbers are required. In addition, it is demonstrated that to capture flow dynamics in the high drag reduction (HDR) and MDR regimes, very long computational domain lengths of the order of 10 4 wall units are required. The simulation results in turn have been used to develop a scaling that describes the interplay between rheological parameters (i.e., maximum chain extension and relaxation time) and the extent of drag reduction as a function of Reynolds number. In addition, turbulence statistics are analyzed and correlations between the polymer body force and velocity fluctuations have been developed with particular emphasis on the HDR and MDR regimes. These observations have been used to decipher the effect of polymer additives on the dynamics of the flow and drag reduction.
doi_str_mv	10.1016/j.jnnfm.2005.12.012
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It is shown that to obtain significant levels of drag reduction large polymer chain extensibility and high Weissenberg numbers are required. In addition, it is demonstrated that to capture flow dynamics in the high drag reduction (HDR) and MDR regimes, very long computational domain lengths of the order of 10 4 wall units are required. The simulation results in turn have been used to develop a scaling that describes the interplay between rheological parameters (i.e., maximum chain extension and relaxation time) and the extent of drag reduction as a function of Reynolds number. In addition, turbulence statistics are analyzed and correlations between the polymer body force and velocity fluctuations have been developed with particular emphasis on the HDR and MDR regimes. 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It is shown that to obtain significant levels of drag reduction large polymer chain extensibility and high Weissenberg numbers are required. In addition, it is demonstrated that to capture flow dynamics in the high drag reduction (HDR) and MDR regimes, very long computational domain lengths of the order of 10 4 wall units are required. The simulation results in turn have been used to develop a scaling that describes the interplay between rheological parameters (i.e., maximum chain extension and relaxation time) and the extent of drag reduction as a function of Reynolds number. In addition, turbulence statistics are analyzed and correlations between the polymer body force and velocity fluctuations have been developed with particular emphasis on the HDR and MDR regimes. These observations have been used to decipher the effect of polymer additives on the dynamics of the flow and drag reduction.</abstract><cop>Amsterdam</cop><pub>Elsevier B.V</pub><doi>10.1016/j.jnnfm.2005.12.012</doi><tpages>18</tpages></addata></record>
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subjects	Computational methods in fluid dynamics Dilute polymeric solutions Direct numerical simulation (DNS) Drag reduction Exact sciences and technology FENE-P model Flows in ducts, channels, nozzles, and conduits Fluid dynamics Fundamental areas of phenomenology (including applications) Oldroyd-B model Physics Spectral techniques Turbulence control Turbulent channel flows Turbulent flows, convection, and heat transfer
title	Influence of rheological parameters on polymer induced turbulent drag reduction
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