Secondary flows in slow granular flows

Recent findings by Krishnaraj and Nott [1] show that a granular material sheared in a cylindrical Couette cell at low shear rates forms a single secondary vortex. The vortex spans the entire width of the Couette cell and has a sense opposite to the centrifugally driven Taylor-Couette vortex in a New...

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Main Authors: Dsouza Peter Varun, Krishnaraj K.P., Nott Prabhu R
Format: Article
Language:English
Published: EDP Sciences 2017-01-01
Series:EPJ Web of Conferences
Online Access:https://doi.org/10.1051/epjconf/201714003028
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spelling doaj-caf3b06ed37a4fd2b1a98681d0e9552a2021-08-02T09:15:31ZengEDP SciencesEPJ Web of Conferences2100-014X2017-01-011400302810.1051/epjconf/201714003028epjconf162071Secondary flows in slow granular flowsDsouza Peter Varun0Krishnaraj K.P.1Nott Prabhu R2Indian Institute of ScienceIndian Institute of ScienceIndian Institute of ScienceRecent findings by Krishnaraj and Nott [1] show that a granular material sheared in a cylindrical Couette cell at low shear rates forms a single secondary vortex. The vortex spans the entire width of the Couette cell and has a sense opposite to the centrifugally driven Taylor-Couette vortex in a Newtonian fluid – it is in fact shown to be driven by shear-induced dilation. Krishnaraj and Nott [1] show that the vortex also explains a Theological anomaly observed earlier [2], wherein all components of the stress on the outer cylinder increase nearly exponentially with depth from the free surface. In this study, we test the robustness of this vortex by varying the parameters of the grain contact model. We show that the presence of a free surface is not essential for the formation of the secondary vortex. The vortex forms even when a rigid plate of finite weight confines the granular column at the top. We find that as the shear rate is increased, an additional centrifugally-driven vortex appears. This new vortex keeps growing until, at Savage number close to one, the dilation-driven vortex disappears. We also present the variation of the wall stresses at the inner cylinder with depth. Finally, we argue that the secondary flow can also help to understand the rheological behaviour observed in geometries such as the split-bottom Couette device [3].https://doi.org/10.1051/epjconf/201714003028
collection DOAJ
language English
format Article
sources DOAJ
author Dsouza Peter Varun
Krishnaraj K.P.
Nott Prabhu R
spellingShingle Dsouza Peter Varun
Krishnaraj K.P.
Nott Prabhu R
Secondary flows in slow granular flows
EPJ Web of Conferences
author_facet Dsouza Peter Varun
Krishnaraj K.P.
Nott Prabhu R
author_sort Dsouza Peter Varun
title Secondary flows in slow granular flows
title_short Secondary flows in slow granular flows
title_full Secondary flows in slow granular flows
title_fullStr Secondary flows in slow granular flows
title_full_unstemmed Secondary flows in slow granular flows
title_sort secondary flows in slow granular flows
publisher EDP Sciences
series EPJ Web of Conferences
issn 2100-014X
publishDate 2017-01-01
description Recent findings by Krishnaraj and Nott [1] show that a granular material sheared in a cylindrical Couette cell at low shear rates forms a single secondary vortex. The vortex spans the entire width of the Couette cell and has a sense opposite to the centrifugally driven Taylor-Couette vortex in a Newtonian fluid – it is in fact shown to be driven by shear-induced dilation. Krishnaraj and Nott [1] show that the vortex also explains a Theological anomaly observed earlier [2], wherein all components of the stress on the outer cylinder increase nearly exponentially with depth from the free surface. In this study, we test the robustness of this vortex by varying the parameters of the grain contact model. We show that the presence of a free surface is not essential for the formation of the secondary vortex. The vortex forms even when a rigid plate of finite weight confines the granular column at the top. We find that as the shear rate is increased, an additional centrifugally-driven vortex appears. This new vortex keeps growing until, at Savage number close to one, the dilation-driven vortex disappears. We also present the variation of the wall stresses at the inner cylinder with depth. Finally, we argue that the secondary flow can also help to understand the rheological behaviour observed in geometries such as the split-bottom Couette device [3].
url https://doi.org/10.1051/epjconf/201714003028
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