Settling dynamics of an oloid: experiments and simulations

Abstract

This study presents a combined experimental and computational investigation of an oloid shaped particle settling in a quiescent fluid. The oloid, a unique convex shape with anisotropic geometry, provides a distinctive model for exploring how a particle's shape and orientation affect its settling dynamics. The settling oloids are tracked experimentally for Galileo numbers 48 ≤ Ga ≤ 5.4 · 103, using two particle sizes (Deq = 21.6 mm, and Deq = 10.8 mm). The density ratio between the particle and fluid = pf ranges from 1.11 ≤ ≤ 1.30 in the experiments. Computationally, the Galileo numbers 10 ≤ Ga ≤ 100 are simulated, with = 2. The experimental findings and numerical results are in good agreement, and give a consistent idea of the oloid settling dynamics. Our results indicate two distinct falling modes for the oloid, separated by Galileo number. The stable mode is characterised by a preferential orientation, with a rotation around the vertical axis, whereas the tumbling mode has randomly distributed orientation and rotation statistics. We characterise the falling velocity, orientation, and rotation dynamics of the oloids over a range of Galileo numbers. Additionally, the influence of the initial orientation is revealed to determine the rotation dynamics at low Galileo numbers.

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