Equilibrium theory of bidensity particle-laden suspensions in thin-film flow down a spiral separator
Lingyun Ding, Sarah C. Burnett, Andrea L. Bertozzi
TL;DR
This paper develops a theoretical model for bidensity particle-laden thin-film flows in spiral separators, revealing radial separation mechanisms for different particle densities and analyzing how design parameters affect separation efficiency.
Contribution
It extends existing models to multi-species systems, incorporating particle interactions and deriving equilibrium profiles for practical spiral separator design.
Findings
Radial separation occurs for particles of different densities.
Equilibrium concentration and fluid depth profiles are derived.
Design parameters like spiral radius influence separation profiles.
Abstract
Spiral gravity separators are designed to separate multi-species slurry components based on differences in density and size. Previous studies have investigated steady-state solutions for mixtures of liquids and single particle species in thin-film flows. However, these models are constrained to single-species systems and cannot describe the dynamics of multi-species separation. In contrast, our analysis extends to mixtures containing two particle species of differing densities, revealing that they undergo radial separation, which is an essential mechanism for practical applications in separating particles of varying densities. This work models gravity-driven bidensity slurries in a spiral trough by incorporating particle interactions, using empirically derived formulas for particle fluxes from previous bidensity studies on inclined planes. Specifically, we study a thin-film bidensity…
Peer Reviews
No public reviews on file for this paper yet. If you reviewed it on a platform where reviews are public (OpenReview, ICLR, NeurIPS, ICML), you can paste yours below so the community can read it here.
Videos
No videos yet. Explain this paper in a talk, walkthrough, or lecture? Add one.
Taxonomy
TopicsParticle Dynamics in Fluid Flows · Rheology and Fluid Dynamics Studies · Fluid Dynamics and Thin Films