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Article type: Research Article
Authors: Wang, S.K. | Hwang, N.H.C.
Affiliations: Department of Biomedical Engineering, University of Miami, Coral Gables, Florida 33124, USA
Abstract: The motion of a single, spherical particle, released at different radial positions at the inlet of the entrance region of a straight circular laminar flow tube (Re = 260), was studied theoretically. Radial migration of the particle, either toward the tube center or toward the tube wall, was predicted. Based on the hypothesis that the particle experienced a lift force which was produced by the vorticity in the boundary layer and a velocity difference between the center of the suspended particle and the fluid medium, an inertia-vorticity fluid dynamic model was formulated to analyze the particle radial motions. Computational flow dynamics (CFD) solutions obtained from a 9.8 mm diameter tube model included the resulting particle loci for three particle radii (a = 0.1 cm, 0.085 cm, 0.050 cm), with the particle entry at various radial positions. The computation also covered a range of different particle entry speeds. The results showed that the particle migrates toward the tube center if it lags behind the medium in the core region; otherwise, it migrates toward the tube wall. Additional flow experiments were conducted in a circular (2R = 10.2 mm), 300 mm long straight tube. A small polystyrene sphere (2a = 1.72 mm, density ρp=1.014g·cm−3) was released at the inlet (X = 0, η/R=0.48) with two dimensionless release velocities (ωp=0, and ωp>1.0). The recorded particle traces agree well with the computational model.
Keywords: Laminar tube flow, entrance region, single particle, radial migration, inertia-vorticity effect, numerical model
DOI: 10.3233/BIR-1994-31504
Journal: Biorheology, vol. 31, no. 5, pp. 549-563, 1994
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