TY - JOUR
T1 - Scaling sets the limits of large scale membrane distillation modules for the treatment of high salinity feeds
AU - Soukane, Sofiane
AU - Elcik, Harun
AU - Alpatova, Alla
AU - Orfi, Jamel
AU - Ali, Emad
AU - AlAnsary, Hany
AU - Ghaffour, NorEddine
N1 - KAUST Repository Item: Exported on 2020-12-19
Acknowledged KAUST grant number(s): REP/1/3805-01-01
Acknowledgements: The research reported in this paper was supported by King Abdullah University of Science and Technology (KAUST), Saudi Arabia, through the KAUST-KSU (King Saud University) initiative, Grant # REP/1/3805-01-01 (KAUST) and RG-1440-103 (KSU). The authors acknowledge the help, assistance and support from the Water Desalination and Reuse Center (WDRC) and KAUST staff.
PY - 2020/12
Y1 - 2020/12
N2 - In this study, the dynamics of scaled-up membrane distillation (MD) modules are tackled for the treatment of highly saline desalination brines. Physical phenomena occurring inside the feed chamber during process scale-up including temperature evolution, species distribution and scaling likeliness were explored using a multicomponent computational fluid dynamics (CFD) model that couples momentum, heat, ions transport and water permeation across the membrane. The model was calibrated with experiments carried out on a lab-scale direct contact MD system fed with concentrated seawater with a salinity of 61 g/L. The complete fall-off of the permeate flux occurred when the salinity reached 170 g/L from 61 g/L, caused by a scaling mostly due to calcium sulfate (gypsum). In order to predict scaling occurrence, an in-house code is embedded in the CFD model to solve Pitzer’s equation at every cell of the domain, enabling the calculation of species activity coefficients, the feed ionic strength, species effective concentration and degree of saturation of the solution with respect to gypsum. Results unveil that during the MD process of brines, the degree of saturation increases considerably in membrane vicinity while the average outlet salinity remains close to that at the inlet due to the relatively high flow rate. Extrapolation to longer modules revealed that an increase in the feed temperature increases the scaling likeliness while flow rates, especially in the high range, did not significantly impact scaling formation. The drop in performance from lab-scale module to a scaled-up size is shown for 1 m long generic modules with and without the use of antiscalants.
AB - In this study, the dynamics of scaled-up membrane distillation (MD) modules are tackled for the treatment of highly saline desalination brines. Physical phenomena occurring inside the feed chamber during process scale-up including temperature evolution, species distribution and scaling likeliness were explored using a multicomponent computational fluid dynamics (CFD) model that couples momentum, heat, ions transport and water permeation across the membrane. The model was calibrated with experiments carried out on a lab-scale direct contact MD system fed with concentrated seawater with a salinity of 61 g/L. The complete fall-off of the permeate flux occurred when the salinity reached 170 g/L from 61 g/L, caused by a scaling mostly due to calcium sulfate (gypsum). In order to predict scaling occurrence, an in-house code is embedded in the CFD model to solve Pitzer’s equation at every cell of the domain, enabling the calculation of species activity coefficients, the feed ionic strength, species effective concentration and degree of saturation of the solution with respect to gypsum. Results unveil that during the MD process of brines, the degree of saturation increases considerably in membrane vicinity while the average outlet salinity remains close to that at the inlet due to the relatively high flow rate. Extrapolation to longer modules revealed that an increase in the feed temperature increases the scaling likeliness while flow rates, especially in the high range, did not significantly impact scaling formation. The drop in performance from lab-scale module to a scaled-up size is shown for 1 m long generic modules with and without the use of antiscalants.
UR - http://hdl.handle.net/10754/666433
UR - https://linkinghub.elsevier.com/retrieve/pii/S0959652620356018
U2 - 10.1016/j.jclepro.2020.125555
DO - 10.1016/j.jclepro.2020.125555
M3 - Article
SN - 0959-6526
SP - 125555
JO - Journal of Cleaner Production
JF - Journal of Cleaner Production
ER -