Hostname: page-component-cd9895bd7-gbm5v Total loading time: 0 Render date: 2024-12-25T05:59:13.622Z Has data issue: false hasContentIssue false

Direct Numerical Simulations of Turbulent Channel Flow With Polymer Additives

Published online by Cambridge University Press:  06 August 2020

Che-Yu Lin
Affiliation:
Department of Power Mechanical Engineering National Tsing Hua UniversityHsinchu30013, Taiwan
Chao-An Lin*
Affiliation:
Department of Power Mechanical Engineering National Tsing Hua UniversityHsinchu30013, Taiwan
*
*Corresponding author ([email protected])
Get access

Abstract

Direct numerical simulations have been applied to simulate flows with polymer additives. FENE-P (finite-extensible-nonlinear-elastic-Peterlin) dumbbell model solving for the conformation tensor is adopted to investigate the influence of the polymer on the flowfield. Boundary treatments of the conformation tensor on the flowfield are examined first, where boundary condition based on the linear extrapolation scheme provides more accurate results with second-order accurate error norms. Further simulations of the turbulent channel flow at different Weissenberg numbers are also conducted to investigate the influence on drag reduction. Drag reduction increases in tandem with the increase of Weissenberg number and the increase saturates at Weτ~200, where the drag reduction is close to the maximum drag reduction (MDR) limit. At the regime of y+ > 5, the viscous layer thickens with the increase of the Weissenberg number showing a departure from the traditional log-law profile, and the velocity profiles approach the MDR line at high Weissenberg number. The Reynolds stress decreases in tandem with the increase of Weτ, whereas the levels of laminar stress and polymer stress act adversely. However, as the Weissenberg number increases, the proportion of the laminar stress in the total stress increases, and this contributes to the drag reduction of the polymer flow.

Type
Research Article
Copyright
Copyright © 2020 The Society of Theoretical and Applied Mechanics

Access options

Get access to the full version of this content by using one of the access options below. (Log in options will check for institutional or personal access. Content may require purchase if you do not have access.)

References

REFERENCES

Hayat, T., Iqbal, R., Tanveer, A. and Alsaedi, A., “Variable Viscosity Effect on Mhd Peristaltic Flow of Pseudoplastic Fluid in a Tapered Asymmetric Channel,” Journal of Mechanics, 34(3), pp. 363-374 (2018).10.1017/jmech.2016.111CrossRefGoogle Scholar
Lin, J. R., Hung, T. C. and Lin, C. H., “Linear Stability Analysis of Journal Bearings Lubricated with a Non-Newtonian Rabinowitsch Fluid,” Journal of Mechanics, 35(1), pp. 107-112 (2019).10.1017/jmech.2017.48CrossRefGoogle Scholar
Sailaja, A., Srinivas, B. and Sreedhar, I., “Electroviscous Effect of Power Law Fluids in a Slit Microchannel with Asymmetric Wall Zeta Potentials,” Journal of Mechanics, 35(4), pp. 537-547 (2019).10.1017/jmech.2018.25CrossRefGoogle Scholar
Tanveer, A., Hayat, T., Alsaedi, A. and Ahmad, B., “Heat Transfer Analysis for Peristalsis of Mhd Carreau Fluid in a Curved Channel through Modified Darcy Law,” Journal of Mechanics, 35(4), pp. 527-535 (2019).10.1017/jmech.2018.38CrossRefGoogle Scholar
Toms, B. A., “Some observations on the flow of linear polymer solutions through straight tubes at large Reynolds numbers,” Proceedings of 1st international Congress of Rheology, 2 pp. 135-141 (1949).Google Scholar
Dimitropoulos, C. D., Sureshkumar, R., Beris, A. N. and Handler, R. A., “Budgets of Reynolds stress, kinetic energy and streamwise enstrophy in viscoelastic turbulent channel flow,” Physics of Fluids, 13(4), pp. 1016-1027 (2001).10.1063/1.1345882CrossRefGoogle Scholar
Min, T., Choi, H. and Yoo, J. Y., “Maximum drag reduction in a turbulent channel flow by polymer additives,” Journal of Fluid Mechanics, 492 pp. 91-100 (2003).10.1017/S0022112003005597CrossRefGoogle Scholar
Min, T., Jung, Y. Y., Choi, H. and Joseph, D. D., “Drag reduction by polymer additives in a turbulent channel flow,” Journal of Fluid Mechanics, 486 pp. 213-238 (2003).10.1017/S0022112003004610CrossRefGoogle Scholar
Sibilla, S. and Baron, A., “Polymer stress statistics in the near-wall turbulent flow of a drag-reducing solution,” Physics of Fluids, 14(3), pp. 1123-1136 (2002).10.1063/1.1448497CrossRefGoogle Scholar
Dimitropoulos, C. D., Dubief, Y., Shaqfeh, E. S. G. and Moin, P., “Direct numerical simulation of polymer-induced drag reduction in turbulent boundary layer flow of inhomogeneous polymer solutions,” Journal of Fluid Mechanics, 566 pp. 153-162 (2006).10.1017/S0022112006002321CrossRefGoogle Scholar
Procaccia, I., L’vov, V. S. and Benzi, R., “Colloquium: Theory of drag reduction by polymers in wall- bounded turbulence,” Reviews of Modern Physics, 80(1), pp. 225-247 (2008).10.1103/RevModPhys.80.225CrossRefGoogle Scholar
Oldroyd, J. G., “Non-Newtonian Effects in Steady Motion of Some Idealized Elastico-Viscous Liquids,” Proceedings of the Royal Society of London Series a- Mathematical and Physical Sciences, 245(1241), pp. 278-297 (1958).Google Scholar
Peterlin, A., “Gradient Dependence of Intrinsic Viscosity of Freely Flexible Linear Macromolecules,” Journal of Chemical Physics, 33(6), pp. 1799-1802 (1960).10.1063/1.1731506CrossRefGoogle Scholar
Thien, N. P. and Tanner, R. I., “A new constitutive equation derived from network theory,” Journal of Non-Newtonian Fluid Mechanics, 2(4), pp. 353-365 (1977).10.1016/0377-0257(77)80021-9CrossRefGoogle Scholar
Giesekus, H., “A Simple Constitutive Equation for Polymer Fluids Based on the Concept of Deformation-Dependent Tensorial Mobility,” Journal of Non-Newtonian Fluid Mechanics, 11(1-2), pp. 69-109 (1982).10.1016/0377-0257(82)85016-7CrossRefGoogle Scholar
Vaithianathan, T., Robert, A., Brasseur, J. G. and Collins, L. R., “An improved algorithm for simulating three-dimensional, viscoelastic turbulence,” Journal of Non-Newtonian Fluid Mechanics, 140(1-3), pp. 3-22 (2006).10.1016/j.jnnfm.2006.03.018CrossRefGoogle Scholar
Sureshkumar, R. and Beris, A. N., “Effect of Artificial Stress Diffusivity on the Stability of Numerical- Calculations and the Flow Dynamics of Time-Dependent Viscoelastic Flows,” Journal of Non-Newtonian Fluid Mechanics, 60(1), pp. 53-80 (1995).10.1016/0377-0257(95)01377-8CrossRefGoogle Scholar
Min, T., Yoo, J. Y. and Choi, H., “Effect of spatial discretization schemes on numerical solutions of viscoelastic fluid flows,” Journal of Non-Newtonian Fluid Mechanics, 100(1-3), pp. 27-47 (2001).10.1016/S0377-0257(01)00128-8CrossRefGoogle Scholar
Yu, B. and Kawaguchi, Y., “Direct numerical simulation of viscoelastic drag-reducing flow: a faithful finite difference method,” Journal of Non-Newtonian Fluid Mechanics, 116(2-3), pp. 431-466 (2004).10.1016/j.jnnfm.2003.11.006CrossRefGoogle Scholar
Fattal, R. and Kupferman, R., “Constitutive laws for the matrix-logarithm of the conformation tensor,” Journal of Non-Newtonian Fluid Mechanics, 123(2-3), pp. 281-285 (2004).10.1016/j.jnnfm.2004.08.008CrossRefGoogle Scholar
Balci, N., Thomases, B., Renardy, M. and Doering, C. R., “Symmetric factorization of the conformation tensor in viscoelastic fluid models,” Journal of Non-Newtonian Fluid Mechanics, 166(11), pp. 546-553 (2011).10.1016/j.jnnfm.2011.02.008CrossRefGoogle Scholar
Afonso, A. M., Pinho, F. T. and Alves, M. A., “The kernel-conformation constitutive laws,” Journal of Non-Newtonian Fluid Mechanics, 167 pp. 30-37 (2012).Google Scholar
Chen, X. Y., Marschall, H., Schafer, M. and Bothe, D., “A comparison of stabilisation approaches for finite-volume simulation of viscoelastic fluid flow,” International Journal of Computational Fluid Dynamics, 27(6-7), pp. 229-250 (2013).10.1080/10618562.2013.829916CrossRefGoogle Scholar
Dallas, V., Vassilicos, J. C. and Hewitt, G. F., “Strong polymer-turbulence interactions in viscoelastic turbulent channel flow,” Physical Review E, 82(6), (2010).10.1103/PhysRevE.82.066303CrossRefGoogle ScholarPubMed
Chen, J. C. and Lin, C. A., “Computations of strongly swirling flows with second-moment closures,” International Journal for Numerical Methods in Fluids, 30(5), pp. 493-508 (1999).10.1002/(SICI)1097-0363(19990715)30:5<493::AID-FLD849>3.0.CO;2-33.0.CO;2-3>CrossRefGoogle Scholar
Lo, W. and Lin, C. A., “Mean and turbulence structures of Couette-Poiseuille flows at different mean shear rates in a square duct,” Physics of Fluids, 18(6), (2006).10.1063/1.2210019CrossRefGoogle Scholar
Hsu, H.-W., Hsu, J.-B., Lo, W. and Lin, C.-A., “Large eddy simulations of turbulent Couette–Poiseuille and Couette flows inside a square duct,” Journal of Fluid Mechanics, 702 pp. 89-101 (2012).10.1017/jfm.2012.160CrossRefGoogle Scholar
Owolabi, B. E. and Lin, C. A., “Marginally turbulent Couette flow in a spanwise confined passage of square cross section,” Physics of Fluids, 30(7), (2018).10.1063/1.5026947CrossRefGoogle Scholar
Liao, C. C. and Lin, C. A., “Transitions of natural convection flows in a square enclosure with a heated circular cylinder,” Applied Thermal Engineering, 72(1), pp. 41-47 (2014).10.1016/j.applthermaleng.2014.02.071CrossRefGoogle Scholar
Roe, P. L., “Characteristic-Based Schemes for the Euler Equations,” Annual Review of Fluid Mechanics, 18 pp. 337-365 (1986).CrossRefGoogle Scholar
Cruz, D. O. A., Pinho, F. T. and Oliveira, P. J., “Analytical solutions for fully developed laminar flow of some viscoelastic liquids with a Newtonian solvent contribution,” Journal of Non-Newtonian Fluid Mechanics, 132(1-3), pp. 28-35 (2005).10.1016/j.jnnfm.2005.08.013CrossRefGoogle Scholar
Zhang, M. Q., Lashgari, I., Zaki, T. A. and Brandt, L., “Linear stability analysis of channel flow of viscoelastic Oldroyd-B and FENE-P fluids,” Journal of Fluid Mechanics, 737 pp. 249-279 (2013).CrossRefGoogle Scholar
Housiadas, K. D. and Beris, A. N., “Characteristic scales and drag reduction evaluation in turbulent channel flow of nonconstant viscosity viscoelastic fluids,” Physics of Fluids, 16(5), pp. 1581-1586 (2004).CrossRefGoogle Scholar
Warholic, M. D., Massah, H. and Hanratty, T. J., “Influence of drag-reducing polymers on turbulence: effects of Reynolds number, concentration and mixing,” Experiments in Fluids, 27(5), pp. 461-472 (1999).CrossRefGoogle Scholar
Virk, P. S., “Drag Reduction Fundamentals,” Aiche Journal, 21(4), pp. 625-656 (1975).CrossRefGoogle Scholar
Abe, H., Kawamura, H. and Matsuo, Y., “Direct numerical simulation of a fully developed turbulent channel flow with respect to the Reynolds number dependence,” Journal of Fluids Engineering-Transactions of the Asme, 123(2), pp. 382-393 (2001).CrossRefGoogle Scholar
Ptasinski, P. K., Nieuwstadt, F. T. M., van den Brule, B. H. A. A. and Hulsen, M. A., “Experiments in turbulent pipe flow with polymer additives at maximum drag reduction,” Flow Turbulence and Combustion, 66(2), pp. 159-182 (2001).CrossRefGoogle Scholar