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http://dx.doi.org/10.12989/csm.2018.7.4.407

Hydrodynamic coupling distance between a falling sphere and downstream wall  

Lin, Cheng-Chuan (Department of Mechanical Engineering, National Taiwan University)
Huang, Hung-Tien (Department of Mechanical Engineering, National Taiwan University)
Yang, Fu-Ling (Department of Mechanical Engineering, National Taiwan University)
Publication Information
Coupled systems mechanics / v.7, no.4, 2018 , pp. 407-420 More about this Journal
Abstract
In solid-liquid two phase flow, the knowledge of how descending solid particles affected by the presence of downstream wall is important. This work studies at what interstitial distance the velocity of a vertically descending sphere is affected by a downstream wall as a consequence of wall-modified hydrodynamic forces through a validated dynamic model. This interstitial distance-the hydrodynamic coupling distance ${\delta}_c-is$ found to decay monotonically with the approach Stokes number St which compares the particle inertia to viscous drag characterized by the quasi-steady Stokes' drag. The scaling relation ${\delta}_c-St-1$ decays monotonically as literature below the value of St equal to 10. However, the faster diminishing rate is found above the threshold value from St=10-40. Furthermore, an empirical relation of ${\delta}_c-St$ shows dependence on the drop height which clearly indicates the non-negligible effect of unsteady hydrodynamic force components, namely the added mass force and the history force. Finally, we attempt a fitting relation which embedded the particle acceleration effect in the dependence of fitting constants on the diameter-scaled drop height.
Keywords
hydrodynamic coupling; Stokes number; wall effect; added mass force; history force;
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Times Cited By KSCI : 3  (Citation Analysis)
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