Modeling of viscoelastic turbulent flow in channel and pipe

Yang, Shu-Qing; Dou, Guoren

doi:10.1063/1.2920275

Cited by 11 publications

(3 citation statements)

References 41 publications

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“…If δ * → 0 but c is large, then eq. ( 71) predicts v [δ * ] ∝ δ * and then the parametric relations become f ∝ Re −1/2 , in reasonable agreement with Virk's asymptote [15,[33][34][35][36]. We see however that even for large concentrations drag reduction will be very small as long as δ * ≫ δ 0…”

Section: Identifying the Free Parameterssupporting

confidence: 69%

Drag reduction by polymer additives from turbulent spectra

Calzetta

2010

Phys. Rev. E

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Section: Identifying the Free Parameterssupporting

confidence: 69%

Drag reduction by polymer additives from turbulent spectra

Calzetta

2010

Phys. Rev. E

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“…Another recent approach is based on phenomenological ansatzes regarding Reynolds shear stresses and eddy viscosities . In particular, Benzi and coworkers combine these ideas with the observation that in some experiments (e.g., Ref.…”

Section: Introductionmentioning

confidence: 97%

Time‐series and extended Karhunen–Loève analysis of turbulent drag reduction in polymer solutions

et al. 2014

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in Wiley Online Library (wileyonlinelibrary.com) Direct numerical simulations and statistical analysis techniques are used to study the drag-reducing effect of polymer additives on turbulent channel flow in minimal domains. Additionally, a new formulation of Karhunen-Loe`ve decomposition for viscoelastic flows is introduced, allowing the dominant features of the polymer stress fields to be characterized. In minimal channels, there are intervals of "active" and "hibernating" turbulence that display very different structural and energetic characteristics; the present work illustrates how the statistics of these intervals evolve over the entire range of drag reduction (DR) levels. The effect of viscoelasticity on minimal channel turbulence is twofold: first, it strongly suppresses the active turbulent dynamics that predominate in Newtonian flow and second, at sufficiently high Weissenberg number it stabilizes the dynamics of hibernating turbulence, allowing it to predominate in the maximum drag reduction regime. In this regime, the stress fluctuations become delocalized from the wall region, encompassing the entire flow domain.

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“…If −u v = 0, one can obtain the velocity u + l in laminar flow from (12), and by modelling the Reynolds shear stress in (12), Dou obtained the velocity u + in fully turbulent flow (Yang & Dou 2008 …”

Section: Introductionmentioning

confidence: 99%

Turbulent drag reduction with polymer additive in rough pipes

Yang

Dou

2009

J. Fluid Mech.

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Friction factor of drag-reducing flow with presence of polymers in a rough pipe has been investigated based on the eddy diffusivity model, which shows that the ratio of effective viscosity caused by polymers to kinematic viscosity of fluid should be proportional to the Reynolds number, i.e. u * R/ν and the proportionality factor depends on polymer's type and concentration. A formula of flow resistance covering all regions from laminar, transitional and fully turbulent flows has been derived, and it is valid in hydraulically smooth, transitional and fully rough regimes. This new formula has been tested against Nikuradse and Virk's experimental data in both Newtonian and non-Newtonian fluid flows. The agreement between the measured and predicted friction factors is satisfactory, indicating that the addition of polymer into Newtonian fluid flow leads to the non-zero effective viscosity and it also thickens the viscous sublayer, subsequently the drag is reduced. The investigation shows that the effect of polymer also changes the velocity at the top of roughness elements. Both experimental data and theoretical predictions indicate that, if same polymer solution is used, the drag reduction (DR) in roughened pipes becomes smaller relative to smooth pipe flows at the same Reynolds number.

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Modeling of viscoelastic turbulent flow in channel and pipe

Cited by 11 publications

References 41 publications

Drag reduction by polymer additives from turbulent spectra

Drag reduction by polymer additives from turbulent spectra

Time‐series and extended Karhunen–Loève analysis of turbulent drag reduction in polymer solutions

Turbulent drag reduction with polymer additive in rough pipes

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