Unraveling the role of feed temperature and cross-flow velocity on organic fouling in membrane distillation using response surface methodology

Understanding the role of operating condition on fouling development in membrane distillation (MD) is critical for the further optimization of MD technology. In this study, organic fouling development in MD was investigated varying the feed inlet temperature from 35 to 65 degrees C and the cross-flow velocity from 0.21 to 0.42 m/s. The fouling layer thickness was estimated at the end of each experiment non-invasively with optical coherence tomography. The set of experiments was mined to model the initial flux decline, the near-stable flux, and the final foulant thickness responses by central composite design, a useful response surface methodology (RSM) tool. The results indicated a linear increment of the fouling thickness by increasing the feed inlet temperatures. Overall, the feed inlet temperature governed both the initial flux decline and the fouling deposition. The benefits in water productivity obtained by increasing the feed temperature were always offset by higher fouling deposition. Higher cross-flow velocities showed a positive effect on the initial flux, which however translated in larger values of the initial flux decline rate. On the other hand, the higher shear stress contributed to a decrease of the final steadystate fouling layer thickness. The proposed approach was proven to be a valuable tool to assess the role of the operating conditions on fouling and process performance in MD.

Automated summary

Understanding the impact of operating conditions on fouling development in membrane distillation is crucial for optimizing the technology. This study investigated the organic fouling development in MD by varying the feed inlet temperature and cross-flow velocity. The results showed that increasing the feed temperature led to thicker fouling layers, while higher cross-flow velocities improved the initial flux but also increased the decline rate. Higher shear stress contributed to a decrease in the final fouling layer thickness. The proposed approach proved to be a valuable tool for assessing the role of operating conditions on fouling and process performance in MD.