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Main Authors: Drumm, Abigail Rose, Bernardi, Francesca
Format: Preprint
Published: 2025
Subjects:
Online Access:https://arxiv.org/abs/2508.18262
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author Drumm, Abigail Rose
Bernardi, Francesca
author_facet Drumm, Abigail Rose
Bernardi, Francesca
contents Membrane filtration is widely used in water treatment to remove foulants from contaminated water. Foulant build-up on the membrane occludes the area open for fluid flow, which impairs the efficiency of the filtration operation by decreasing the flux through the membrane. Backwashing is a strategy to restore the membrane, wherein clean water is processed backward through the membrane to dislodge attached foulants. We develop a Monte Carlo model to simulate constant-pressure forward filtration and backwashing through dead-end, flat-sheet membranes, with membrane fouling dominated by intermediate blocking. We validate our model against real-world experiments conducted with different foulant types and concentrations and run under different filtration conditions. Relying primarily on measurable physical parameters and employing easy-to-implement parameter fitting techniques as needed, we show good agreement between experimental data and numerical simulations. We extend these results to predict flux behavior in forward filtration and backwashing when foulant properties or filtration conditions are varied. The newly developed model can be used to further investigate the impact of varying backwashing duration, frequency, and/or pressure on the rate of flux recovery.
format Preprint
id arxiv_https___arxiv_org_abs_2508_18262
institution arXiv
publishDate 2025
record_format arxiv
spellingShingle Monte Carlo simulations of 2D flat-sheet membrane filters for constant-pressure water purification
Drumm, Abigail Rose
Bernardi, Francesca
Fluid Dynamics
Membrane filtration is widely used in water treatment to remove foulants from contaminated water. Foulant build-up on the membrane occludes the area open for fluid flow, which impairs the efficiency of the filtration operation by decreasing the flux through the membrane. Backwashing is a strategy to restore the membrane, wherein clean water is processed backward through the membrane to dislodge attached foulants. We develop a Monte Carlo model to simulate constant-pressure forward filtration and backwashing through dead-end, flat-sheet membranes, with membrane fouling dominated by intermediate blocking. We validate our model against real-world experiments conducted with different foulant types and concentrations and run under different filtration conditions. Relying primarily on measurable physical parameters and employing easy-to-implement parameter fitting techniques as needed, we show good agreement between experimental data and numerical simulations. We extend these results to predict flux behavior in forward filtration and backwashing when foulant properties or filtration conditions are varied. The newly developed model can be used to further investigate the impact of varying backwashing duration, frequency, and/or pressure on the rate of flux recovery.
title Monte Carlo simulations of 2D flat-sheet membrane filters for constant-pressure water purification
topic Fluid Dynamics
url https://arxiv.org/abs/2508.18262