Settling behaviour of thin curved particles in quiescent fluid and turbulence
Settling behaviour of thin curved particles in quiescent fluid and turbulence
The motion of thin curved falling particles is ubiquitous in both nature and industry but is not yet widely examined. Here, we describe an experimental study on the dynamics of thin cylindrical shells resembling broken bottle fragments settling through quiescent fluid and homogeneous anisotropic turbulence. The particles have Archimedes numbers based on the mean descent velocity 0.75×104≲Ar≲2.75×104. Turbulence reaching a Reynolds number of Reλ≈100 is generated in a water tank using random jet arrays mounted in a coplanar configuration. After the flow becomes statistically stationary, a particle is released and its three-dimensional motion is recorded using two orthogonally positioned high-speed cameras. We propose a simple pendulum model that accurately captures the velocity fluctuations of the particles in still fluid and find that differences in the falling style might be explained by a closer alignment between the particle's pitch angle and its velocity vector. By comparing the trajectories under background turbulence with the quiescent fluid cases, we measure a decrease in the mean descent velocity in turbulence for the conditions tested. We also study the secondary motion of the particles and identify descent events that are unique to turbulence such as ‘long gliding’ and ‘rapid rotation’ events. Lastly, we show an increase in the radial dispersion of the particles under background turbulence and correlate the time scale of descent events with the local settling velocity.
A30-1 - A30-26
T.K. Chan, Timothy
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Blay esteban, Luis
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Huisman, Sander
3be4bdc8-b0b1-473b-a724-3515173bfeae
Shrimpton, John
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Ganapathisubramani, Bharathram
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T.K. Chan, Timothy
09cdc9e1-1745-4f21-802e-a1e6d5c02ee4
Blay esteban, Luis
b2b8781e-a741-436f-ba2a-cc475cd10834
Huisman, Sander
3be4bdc8-b0b1-473b-a724-3515173bfeae
Shrimpton, John
9cf82d2e-2f00-4ddf-bd19-9aff443784af
Ganapathisubramani, Bharathram
5e69099f-2f39-4fdd-8a85-3ac906827052
T.K. Chan, Timothy, Blay esteban, Luis, Huisman, Sander, Shrimpton, John and Ganapathisubramani, Bharathram
(2021)
Settling behaviour of thin curved particles in quiescent fluid and turbulence.
Journal of Fluid Mechanics, 922, .
(doi:10.1017/jfm.2021.520).
Abstract
The motion of thin curved falling particles is ubiquitous in both nature and industry but is not yet widely examined. Here, we describe an experimental study on the dynamics of thin cylindrical shells resembling broken bottle fragments settling through quiescent fluid and homogeneous anisotropic turbulence. The particles have Archimedes numbers based on the mean descent velocity 0.75×104≲Ar≲2.75×104. Turbulence reaching a Reynolds number of Reλ≈100 is generated in a water tank using random jet arrays mounted in a coplanar configuration. After the flow becomes statistically stationary, a particle is released and its three-dimensional motion is recorded using two orthogonally positioned high-speed cameras. We propose a simple pendulum model that accurately captures the velocity fluctuations of the particles in still fluid and find that differences in the falling style might be explained by a closer alignment between the particle's pitch angle and its velocity vector. By comparing the trajectories under background turbulence with the quiescent fluid cases, we measure a decrease in the mean descent velocity in turbulence for the conditions tested. We also study the secondary motion of the particles and identify descent events that are unique to turbulence such as ‘long gliding’ and ‘rapid rotation’ events. Lastly, we show an increase in the radial dispersion of the particles under background turbulence and correlate the time scale of descent events with the local settling velocity.
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SettlingCurvedParticles_5Mar21
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settling-behaviour-of-thin-curved-particles-in-quiescent-fluid-and-turbulence
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Accepted/In Press date: 14 June 2021
e-pub ahead of print date: 16 July 2021
Identifiers
Local EPrints ID: 474813
URI: http://eprints.soton.ac.uk/id/eprint/474813
ISSN: 0022-1120
PURE UUID: d5e225fb-5cae-43fa-82e4-154e48a9ba25
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Date deposited: 03 Mar 2023 17:32
Last modified: 17 Mar 2024 03:22
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Contributors
Author:
Timothy T.K. Chan
Author:
Luis Blay esteban
Author:
Sander Huisman
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