Drag on a Sphere in Poiseuille Flow of Shear-Thinning Power-Law Fluids

Song, Daoyun; Gupta, Rakesh; Chhabra, R.P.

doi:10.1021/ie102120p

Cited by 31 publications

(25 citation statements)

References 33 publications

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“…Table shows such a comparison between the present results for Bn = 10 –3 and that in power-law fluids. Clearly, the close correspondence between the present results and that of Song et al , indicates little or no effect of such a low value of the Bingham number. The reasons for the deviations on the order of 10% in drag values with that of Dhole et al have been advanced by Song et al and thus are not repeated here.…”

Section: Results and Discussionsupporting

confidence: 88%

“…Clearly, the close correspondence between the present results and that of Song et al , indicates little or no effect of such a low value of the Bingham number. The reasons for the deviations on the order of 10% in drag values with that of Dhole et al have been advanced by Song et al and thus are not repeated here. Intuitively, it appears that for given values of the power-law index and Reynolds number, there will be a critical Bingham number above which the effects of the yield stress begin to influence the results.…”

Section: Results and Discussionsupporting

confidence: 88%

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Effect of Shear-Thinning Behavior on Heat Transfer from a Heated Sphere in Yield-Stress Fluids

Nirmalkar

Chhabra

Poole

2013

Ind. Eng. Chem. Res.

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The present study deals with the prediction of drag and forced convection heat transfer behavior of a heated sphere in shear-thinning yield-stress fluids over wide ranges of conditions: plastic Reynolds number, 1 ≤ Re ≤ 100; Prandtl number, 1 ≤ Pr ≤ 100; Bingham number, 10–3 ≤ Bn ≤ 10; and shear-thinning index, 0.2 ≤ n ≤ 1. The momentum and energy equations have been solved numerically together with the Papanastasiou regularization method for viscosity to circumvent the discontinuity inherent in the Herschel–Bulkley constitutive equation. Extensive results on the flow and heat transfer characteristics are presented in order to delineate the influence of the aforementioned dimensionless parameters. Thus, for instance, the flow characteristics are presented in terms of the streamlines, morphology of the yielded/unyielded regions, recirculation length, shear rate magnitude over the surface of the sphere, and drag coefficient. Similarly, heat transfer characteristics are examined in terms of isotherm contours in the close proximity of the sphere and the average Nusselt number as a function of the relevant dimensionless groups. Furthermore, the present results are compared with the available experimental and numerical results in order to establish the reliability and precision of the numerical solution methodology employed in this work. Finally, the average Nusselt number and drag values are correlated in terms of the shear-thinning index (n) and the modified Reynolds number (Re*) via simple expressions, thereby enabling their interpolation for intermediate values of the modified Reynolds number. All else being equal, in addition to Bingham number, shear-thinning behavior of yield stress fluids enhances the rate of heat transfer over and above that observed in Newtonian fluids.

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Section: Results and Discussionsupporting

confidence: 88%

Section: Results and Discussionsupporting

confidence: 88%

Effect of Shear-Thinning Behavior on Heat Transfer from a Heated Sphere in Yield-Stress Fluids

Nirmalkar

Chhabra

Poole

2013

Ind. Eng. Chem. Res.

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“…Interpretation of the data presented by Stratton indicates that for monodisperse polystyrene, n = -0.82 32 . The value of n=1/2 predicted by the model is well within the range of accepted values for shear thinning polymers 34 .…”

Section: Theorysupporting

confidence: 81%

“…The measured dependence of the decrease in the radius with increasing shear rate (power law of -0.08) is in reasonable agreement with the model prediction of -0.16 derived in Equation 8. Furthermore, the model predicts a power law for the viscosity of -0.5 close to the range observed for polymer solutions which vary from -1.0 to -0.2 [32][33][34] . Given that the model uses a first order approximation for the Einstein equation, and the theta condition the model appears a reasonable fit to the dependence of the radius and viscosity with shear rate.…”

Section: Figurementioning

confidence: 53%

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A New Model of Polymers in Flow

Dunstan

2011

CheM

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Recent experimental evidence has shown that polymer chains compress in flow at semi-dilute concentrations. It has been assumed in all models of polymer flow behaviour that the chains extend in flow. A new model of polymers in flow in semi-dilute solution is presented where the chains compress. The chains are modeled as simple Hookean dumbbells exposed to compressive hydrodynamic forces. Equating the hydrodynamic and elastic forces predicts chain compression with shear rate. The model predicts both the power law behaviour observed for polymer shear thinning and the measured decrease in radius with shear rate with reasonable accuracy.

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Falling ball method for determining zero shear and shear‐dependent viscosity of polymeric systems: Solutions, melts, and composites

Suri

Patel

Chhabra

2022

Vinyl Additive Technology

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The falling ball method (FBM) is one of the well‐established techniques for measuring the viscosity of Newtonian liquids at the room as well as at elevated temperatures and pressures. Owing to its simplicity and low cost, the possibility of extending its range of application to non‐Newtonian systems including virgin and filled polymer melts, composites, polymer‐solutions, and so forth, is explored here, In this work, theoretical results for the flow of power‐law fluids past a sphere have been used to extract the values of the zero‐shear viscosity and shear‐dependent viscosity in the low‐shear rate limit. The theoretical scheme outlined here has been validated by presenting comparisons with experimental results for scores of polymer solutions for which both falling sphere and rheological data are available in the literature. Indeed, the good correspondence obtained between these two independent data is encouraging and it is thus possible to use the FBM for shear‐thinning systems when the resulting Reynolds numbers are such that the flow is viscosity‐dominated, and the inertial effects are negligible. This implies that the Reynolds number should be ≤ ~1 for shear‐thinning fluids and ≤ ~10−5 for shear‐thickening fluids.

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Drag on a Sphere in Poiseuille Flow of Shear-Thinning Power-Law Fluids

Cited by 31 publications

References 33 publications

Effect of Shear-Thinning Behavior on Heat Transfer from a Heated Sphere in Yield-Stress Fluids

Effect of Shear-Thinning Behavior on Heat Transfer from a Heated Sphere in Yield-Stress Fluids

A New Model of Polymers in Flow

Falling ball method for determining zero shear and shear‐dependent viscosity of polymeric systems: Solutions, melts, and composites

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