Abstract
The membrane fouling issue has aroused great concern. To improve their antifouling properties, surface grafting with oxidative deposition were employed to amend a polyvinylidene fluoride (PVDF) membrane. The modifiers were amino-modified graphene oxide (AMGO), dopamine (DPA) and 1,3-diaminoguanidine hydrochloride (DAGH). To take bovine serum albumin (BSA, 1 g/l) as an example of organic materials, BSA interception rate and pure water flux recovery rate increased to 93.65% and 66.74%, respectively, while the corresponding values for the original membrane were much lower (72.82% and 31.72%). The optimum synthesis conditions were found to be 1.5 mg/ml of DPA, 1 wt% of DAGH, 2 mg/ml of AMGO, 4 h of DPA oxidation deposition time and 1 h of AMGO grafting time. Many functional groups like C = N, -NH2, C = O and -OH improved the membrane surface hydrophilicity leading to a higher resistance to organic pollution. Dopamine and guanidyl facilitated the antimicrobial performance of the modified membrane, whose antimicrobial rate was up to 96%, while the raw membrane had no antimicrobial activity. The amended membrane possessed 40% higher mechanical strength than the initial one. It could withstand a high pumping suction force. The noteworthy property was that the irreversible fouling rate decreased by 55%. Therefore, the amended membrane could restore its flux much more easily.
Highlights
Polyvinylidene fluoride membrane (PVDF membrane) is a type of organic polymeric materials which are widely employed in membrane separation technology
The optimum synthesis conditions were determined based on the index- flux recovery rate of pure water (FRR)
A promising modified membrane was achieved by coating with modifiers such as amino modified graphene oxide (AMGO), dopamine (DPA) and 1,3-diaminoguanidine hydrochloride (DAGH) by taking surface grafting coupled with the oxidative deposition as the modification methods
Summary
Polyvinylidene fluoride membrane (PVDF membrane) is a type of organic polymeric materials which are widely employed in membrane separation technology. It has outstanding characteristics such as having a simple synthesis process, high strength, low price, etc. It becomes necessary to replace membrane modules frequently to keep the purification efficiency, but the frequent replacement of membrane modules leads to the increase of processing cost (Liu et al 2018). Surface modification is feasible to enhance the anti-fouling performance of PVDF membrane, which can improve the purification efficiency and prolong the service life of membrane modules (Liu et al 2011; Shahkaramipour et al 2017).
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