Journal
JOURNAL OF FLUID MECHANICS
Volume 959, Issue -, Pages -Publisher
CAMBRIDGE UNIV PRESS
DOI: 10.1017/jfm.2023.167
Keywords
plastic materials; rheology
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This study quantitatively explores the fluid physics of oscillatory flow of Bingham material on a solid plate through analytical approximations and numerical computation. It reports four key topological properties concerning the generation and termination of yielded regions. Theoretical results can be used as a basis for oscillatory rheometry to measure the yield stress.
The motion of a finite layer of Bingham material on a solid plate that executes in-plane oscillations was reported previously by Balmforth et al. (J. Non-Newtonian Fluid Mech., vol. 158, issue 1-3, 2009, pp. 46-53). There, it was suggested that multiple yielded regions may arise within the material; this contrasts to start-up flow of the same material for which only one yielded region is generated. Here, we explore quantitatively the fluid physics of this oscillatory flow problem through analytical approximations and further numerical computation. Four new key topological properties concerning the generation and termination of the yielded regions are reported. It is shown that the existence of multiple yielded regions is equivalent to the layer never becoming entirely rigid during the periodic motion. For small inertia, the flow is approximately time-reversible with only a single yielded region generated at the plate. For large inertia, shear stress in the material decays rapidly as a function of distance from the plate. A thin zone of yielded material detaches periodically from the plate, and subsequently terminates within the layer. At high oscillation frequency, there can be any number N of distinct rigid regions, satisfying N = L1 - p(-1) logBJ where B is the Bingham number. It is also shown that for B > 0.5370, there are at most one yielded region and one rigid region throughout the motion. These theoretical results can be used as a basis for oscillatory rheometry, allowing for measurement of the yield stress using existing apparatus.
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