Impacts of flow velocity and microbubbles on water flushing in a horizontal pipeline

Abstract

Water flushing to remove particle sediment is essential for safe and continuous transport of many industrial slurries through pipelines. An efficient flushing strategy may reduce water consumption and the cost associated with water usage, and help water conservation for sustainability. In this study, a computational fluid dynamics (CFD) model coupled with the kinetic theory of granular flow for the flushing process is presented. The CFD models were validated against field data collected from a coal slurry pipeline of 128 km in length, 0.575~m in diameter, achieving an average error of less than 15\% for outlet solid concentration over time. A parametric study evaluated the effects of water velocity (1.88-5.88~m/s), bubble size (50~μ m, 150~μ m, and 1000~μ m) and bubble volume fraction (0.05-0.2) on flushing performance including pipeline cleanness, cleanness efficiency, and water consumption. The obtained outcomes indicate that higher water velocity is preferred and an increase in water velocity from 1.88~m/s to 5.88~m/s reduces the water consumption by 28\%. Large bubbles may hinder the flushing process and increase the water consumption by 23\%. Remarkably, small bubbles facilitates the flushing process and lead to 35\% reduction in water consumption. These effects are attributed to the turbulent characteristics in the pipelines in presence of microbubbles.