TY - JOUR
T1 - Nanobubble-assisted scaling inhibition in membrane distillation for the treatment of high-salinity brine
AU - Farid, Muhammad Usman
AU - Kharraz, Jehad A.
AU - Lee, Cheng Hao
AU - Fang, James Kar Hei
AU - St-Hilaire, Sophie
AU - An, Alicia Kyoungjin
N1 - Funding Information:
This work was supported by the Research Grant Council of Hong Kong through Theme-based Research Scheme (Project No. [T21–604/19-R]), Enviromental Conservation Fund (ECF 05/2020), Marine Conservation Enhancement Fund (MCEF20017), and UK Government – Department of Health and Social Care (DHSC), Global AMR Innovation Fund (GAMRIF), and the International Development Research centre (IDRC), Ottawa, Canada (grant #109050–001). The views expressed herein do not necessarily represent those of IDRC or its Board of Governors.
Publisher Copyright:
© 2021
PY - 2022/2/1
Y1 - 2022/2/1
N2 - In this study, we report the use of nanobubbles (NBs) as a simple and facile approach to effectively delay scaling in membrane distillation (MD) during the treatment of highly saline feed (100 g L−1). Unlike conventional gas bubbling in MD for improving the hydrodynamic flow conditions in the feed channel, here we generated air NBs with an average size of 128.81 nm in the feed stream and examined their impact on membrane scaling inhibition during MD operation. Due to their small size, neutral buoyancy, and negative surface charge, NBs remain in suspension for a longer time (14 days), providing homogenous mixing throughout the entire feed water. The MD performance results revealed that severe membrane scaling happened during the DCMD treatment of high salinity brine in the absence of nanobubbles, which dramatically reduced the distillate flux to zero after 13 h. A one-time addition of air NBs in the saline feed significantly reduced salt precipitation and crystal deposition on the PVDF membrane surface, delayed the occurrence of flux decline, prevented membrane wetting, thereby prolonging the effective MD operating time. With similar feed concentration and operating conditions, only 63% flux decline after 98 h operation was recorded in nanobubble-assisted MD. Two key explanations were suggested for the delayed membrane scaling upon addition of air NBs in the MD feed: (1) NB-induced turbulent flow in the feed channel that increases the surface shear forces at the membrane surface, alleviating both temperature and concentration polarization effect, (2) electrostatic attractions of the counterions to the negatively charged NBs, which reduces the availability of these ions in the bulk feed for scale formation.
AB - In this study, we report the use of nanobubbles (NBs) as a simple and facile approach to effectively delay scaling in membrane distillation (MD) during the treatment of highly saline feed (100 g L−1). Unlike conventional gas bubbling in MD for improving the hydrodynamic flow conditions in the feed channel, here we generated air NBs with an average size of 128.81 nm in the feed stream and examined their impact on membrane scaling inhibition during MD operation. Due to their small size, neutral buoyancy, and negative surface charge, NBs remain in suspension for a longer time (14 days), providing homogenous mixing throughout the entire feed water. The MD performance results revealed that severe membrane scaling happened during the DCMD treatment of high salinity brine in the absence of nanobubbles, which dramatically reduced the distillate flux to zero after 13 h. A one-time addition of air NBs in the saline feed significantly reduced salt precipitation and crystal deposition on the PVDF membrane surface, delayed the occurrence of flux decline, prevented membrane wetting, thereby prolonging the effective MD operating time. With similar feed concentration and operating conditions, only 63% flux decline after 98 h operation was recorded in nanobubble-assisted MD. Two key explanations were suggested for the delayed membrane scaling upon addition of air NBs in the MD feed: (1) NB-induced turbulent flow in the feed channel that increases the surface shear forces at the membrane surface, alleviating both temperature and concentration polarization effect, (2) electrostatic attractions of the counterions to the negatively charged NBs, which reduces the availability of these ions in the bulk feed for scale formation.
KW - Brine treatment
KW - Charge
KW - Hydrodynamic disturbance
KW - Membrane distillation
KW - Nanobubbles
KW - Scaling
UR - http://www.scopus.com/inward/record.url?scp=85121280145&partnerID=8YFLogxK
U2 - 10.1016/j.watres.2021.117954
DO - 10.1016/j.watres.2021.117954
M3 - Journal article
AN - SCOPUS:85121280145
SN - 0043-1354
VL - 209
JO - Water Research
JF - Water Research
M1 - 117954
ER -