Flocculation of suspended cohesive particles in homogeneous isotropic turbulence
Autor: | Eckart Meiburg, Florian Pomes, Kunpeng Zhao, Bofeng Bai, Tian-Jian Hsu, Bernhard Vowinckel |
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Rok vydání: | 2021 |
Předmět: |
Length scale
Flocculation Materials science 010504 meteorology & atmospheric sciences Fluids & Plasmas FOS: Physical sciences 01 natural sciences Mathematical Sciences 010305 fluids & plasmas sediment transport Physics - Geophysics Physics::Fluid Dynamics symbols.namesake Engineering Computer Science::Logic in Computer Science Stokes' law 0103 physical sciences suspensions cohesive sediments Stokes number 0105 earth and related environmental sciences Homogeneous isotropic turbulence Turbulence Mechanical Engineering Fluid Dynamics (physics.flu-dyn) Kolmogorov microscales Physics - Fluid Dynamics Mechanics Condensed Matter Physics Geophysics (physics.geo-ph) Mechanics of Materials symbols Computer Science::Programming Languages Particle Computer Science::Formal Languages and Automata Theory |
Popis: | We investigate the dynamics of cohesive particles in homogeneous isotropic turbulence, based on one-way coupled simulations that include Stokes drag, lubrication, cohesive and direct contact forces. We observe a transient flocculation phase characterized by a growing average floc size, followed by a statistically steady equilibrium phase. We analyze the temporal evolution of floc size and shape due to aggregation, breakage, and deformation. Larger turbulent shear and weaker cohesive forces yield elongated flocs that are smaller in size. Flocculation proceeds most rapidly when the fluid and particle time scales are balanced and a suitably defined Stokes number is \textit{O}(1). During the transient stage, cohesive forces of intermediate strength produce flocs of the largest size, as they are strong enough to cause aggregation, but not so strong as to pull the floc into a compact shape. Small Stokes numbers and weak turbulence delay the onset of the equilibrium stage. During equilibrium, stronger cohesive forces yield flocs of larger size. The equilibrium floc size distribution exhibits a preferred size that depends on the cohesive number. We observe that flocs are generally elongated by turbulent stresses before breakage. Flocs of size close to the Kolmogorov length scale preferentially align themselves with the intermediate strain direction and the vorticity vector. Flocs of smaller size tend to align themselves with the extensional strain direction. More generally, flocs are aligned with the strongest Lagrangian stretching direction. The Kolmogorov scale is seen to limit floc growth. We propose a new flocculation model with a variable fractal dimension that predicts the temporal evolution of the floc size and shape. Comment: accepted for publication in the Journal of Fluid Mechanics |
Databáze: | OpenAIRE |
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