The goal of this study is to elucidate the effect the particle moment of inertia (MOI) has on the dynamics of spherical particles rising in a quiescent and turbulent fluid. To this end, we performed experiments with varying density ratios
$\varGamma$
, the ratio of the particle density and fluid density, ranging from
$0.37$
up to
$0.97$
. At each
$\varGamma$
the MOI was varied by shifting mass between the shell and the centre of the particle to vary
$I^*$
(the particle MOI normalised by the MOI of a particle with the same weight and a uniform mass distribution). Helical paths are observed for low, and ‘three-dimensional (3-D) chaotic’ trajectories at higher values of
$\varGamma$
. The present data suggest no influence of
$I^*$
on the critical value for this transition
$0.42<\varGamma _{{crit}}<0.52$
. For the ‘3-D chaotic’ rise mode, we identify trends of decreasing particle drag coefficient (
$C_d$
) and amplitude of oscillation with increasing
$I^*$
. Due to limited data it remains unclear if a similar dependence exists in the helical regime as well. Path oscillations remain finite for all cases studied and no ‘rectilinear’ mode is encountered, which may be the consequence of allowing for a longer transient distance in the present compared with earlier work. Rotational dynamics did not vary significantly between quiescent and turbulent surroundings, indicating that for the present configuration these are predominantly wake driven.
We report on the mobility and orientation of finite-size, neutrally buoyant, prolate ellipsoids (of aspect ratio
$\varLambda =4$
) in Taylor–Couette flow, using interface-resolved numerical simulations. The set-up consists of a particle-laden flow between a rotating inner and a stationary outer cylinder. The flow regimes explored are the well-known Taylor vortex, wavy vortex and turbulent Taylor vortex flow regimes. We simulate two particle sizes
$\ell /d=0.1$
and
$\ell /d=0.2$
,
$\ell$
denoting the particle major axis and
$d$
the gap width between the cylinders. The volume fractions are
$0.01\,\%$
and
$0.07\,\%$
, respectively. The particles, which are initially randomly positioned, ultimately display characteristic spatial distributions which can be categorised into four modes. Modes (i) to (iii) are observed in the Taylor vortex flow regime, while mode (iv) encompasses both the wavy vortex and turbulent Taylor vortex flow regimes. Mode (i) corresponds to stable orbits away from the vortex cores. Remarkably, in a narrow
$\textit {Ta}$
range, particles get trapped in the Taylor vortex cores (mode (ii)). Mode (iii) is the transition when both modes (i) and (ii) are observed. For mode (iv), particles distribute throughout the domain due to flow instabilities. All four modes show characteristic orientational statistics. The focus of the present study is on mode (ii). We find the particle clustering for this mode to be size-dependent, with two main observations. Firstly, particle agglomeration at the core is much higher for
$\ell /d=0.2$
compared with
$\ell /d=0.1$
. Secondly, the
$\textit {Ta}$
range for which clustering is observed depends on the particle size. For this mode (ii) we observe particles to align strongly with the local cylinder tangent. The most pronounced particle alignment is observed for
$\ell /d=0.2$
at around
$\textit {Ta}=4.2\times 10^5$
. This observation is found to closely correspond to a minimum of axial vorticity at the Taylor vortex core (
$\textit {Ta}=6\times 10^5$
) and we explain why.
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