Instabilities of a freely moving spherical particle in a Newtonian fluid: Direct Numerical Simulation

Li, Yuxiu; Tiwari, Shashank S.; Evans, Geoffrey M.; Nandakumar, Krishnaswamy; Joshi, Jyeshtharaj B.

Title: Instabilities of a freely moving spherical particle in a Newtonian fluid: Direct Numerical Simulation
Creator: Li, Yuxiu; Tiwari, Shashank S.; Evans, Geoffrey M.; Nandakumar, Krishnaswamy; Joshi, Jyeshtharaj B.
Relation: International Journal of Chemical Reactor Engineering Vol. 19, Issue 7, p. 699-715
Publisher Link: http://dx.doi.org/10.1515/ijcre-2020-0151
Publisher: Walter de Gruyter GmbH
Resource Type: journal article
Date: 2021
Description: Direct Numerical Simulations (DNS) were carried out for a freely falling/rising rigid particle in an otherwise quiescent fluid, using a non-Lagrangian multiplier based fictitious domain (FD) method. Validation studies showed that the proposed FD based DNS are in good agreement with the existing experimental results in the transition regime of falling/rising spheres. Simulations done in the transitional regime (50 < Reynolds number (Re) < 1800 and solid-to-fluid density ratios Γ = ρp/ρf from 0.08 to 4), confirmed that (i) a falling spherical particle (Γ = 4) exhibits a helical trajectory in the range 270 < Re < 320, and (ii) a rising particle (Γ = 0.5) shows a zig-zagging trajectory in the same range of Re. This finding closes the uncertainty to the question as to whether or not rising/falling particles exhibit a helical and a zigzagging trajectory. In addition to this, a total of seven distinctive flow regimes were identified, which are as follows: (I) vertical straight path (II) steady oblique path (III) Wavy oblique path (IV) zig-zagging path (for 0.08 < Γ < 1) (V) helical path (for 1 < Γ < 4) (VI) early transition to chaos and (VII) chaotic regime. Regime IV occurs only for light particles (Γ < 1), whereas Regime V occurs only for heavy particles (Γ > 1). Fast Fourier Transform (FFT) analysis characterized the presence of a bimodal frequency similar to that exhibited by flow past an isolated stationary bluff body.
Subject: Direct Numerical Simulation; flow instabilities; particle dynamics; vortex shedding
Identifier: http://hdl.handle.net/1959.13/1460923
Identifier: uon:46070
Identifier: ISSN:1542-6580
Language: eng
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