Sedimentation effects on particle position and inertial deposition in 90{\deg} circular bends

TL;DR

This paper investigates how sedimentation influences particle positions and deposition in 90-degree circular pipe bends, providing new analytical tools to predict particle trajectories and reduce computational complexity in flow analysis.

Contribution

It introduces an analytical solution to predict particle trajectories in pipe bends considering sedimentation effects, reducing reliance on extensive CFD simulations.

Findings

Particles sediment to the bottom half of the pipe

Particle positions upstream are affected by gravity

Analytical predictions match CFD results

Abstract

Laminar fluid-particle flows in bend geometries are present in many industrial, pharmaceutical, and biomedical applications. Particle deposition has been studied extensively; however, little attention has been paid to the effect of particle sedimentation on particle position and deposition in different pipe geometry combinations. This study presented a comprehensive analysis of sedimentation effects on particle flow behaviour in 90{\deg} circular pipe bends of micron particles in laminar pipe flows. Pipe geometry combinations consisted of eight pipe diameters, nine bend radii, and 30 particle diameters in a range of 1 to 100 {\mu}m. The results demonstrated the locations of particles that sedimented to the bottom half of the straight pipe section, and the particle positions upstream from the pipe bend entrance, which was no longer in a fully developed profile. These new locations represent the effects of gravity, pulling the particles down. While obtaining these positions can be found through CFD analysis, we proposed an analytical solution to predict the particle trajectory from different release locations that would help to identify the initial particle distribution at locations upstream to the bend, to obviate the need for long upstream straight pipe sections in the CFD analysis.