Chaotic mixing induced by chevron pattern surfaces: Application to reverse osmosis filtration

• Published in: Chemical engineering research & design Vol. 206; pp. 453 - 468
• Main Authors: Park, Jo Eun, Jung, Seon Yeop, Kang, Tae Gon
• Format: Journal Article
• Language: English
• Published: Elsevier Ltd 01.06.2024
• Subjects: Chaotic mixing; Chevron pattern; Numerical simulation; Patterned membrane; Reverse osmosis filtration; Numerical simulation; Chevron pattern; Patterned membrane; Chaotic mixing; Reverse osmosis filtration
• ISSN: 0263-8762
• DOI: 10.1016/j.cherd.2024.05.025

This study numerically investigates the chaotic mixing induced by chevron patterns and examines its influence on enhanced reverse osmosis (RO) filtration. The primary design variables include the dimensionless groove depth (dp*) and the dimensionless overlapped span (S*) of the patterns. The Reynolds number (Re) varies from 100 to 1000, within laminar flow conditions. We analyze the mixing characteristics using Poincaré sections and quantify mixing progress through the intensity of segregation (Id). For each Re value, a specific combination of dp* and S* induces chaotic mixing. Filtration performance is evaluated based on the permeate flux, total flow rate through the membrane, and Sherwood number. Our study reveals that both chaotic advection and intensified lateral flows near the patterns are essential for enhanced RO filtration. Patterns that induce globally chaotic mixing do not always correlate with optimal filtration performance, highlighting that the degree of chaotic mixing is not directly related to concentration polarization (CP) mitigation or filtration enhancement. Rather, it is the intense lateral flow near the patterns that acts as the decisive factor in achieving superior filtration performance, particularly at higher S* values (S*≥0.75) and with deeper grooves (dp*≥0.2). In terms of energy efficiency, patterned membranes demonstrate superior performance compared to their flat counterparts. [Display omitted] •Chevron pattern membranes are designed to induce chaotic advection in RO.•Globally chaotic mixing are achieved with specific sets of design variables.•Chaotic advection and strong lateral flows are essential for enhanced filtration.•Degree of chaos does not directly correlate with enhanced filtration.•Lateral flow intensity dominates filtration efficiency.