Efficient preparation of ultrathin ceramic wafer membranes for the high-effective treatment of the oilfield produced water

Efficient preparation of ceramic membranes helps to reduce costs and makes them more competitive in the field of wastewater treatment. In this work, an ultrathin Al2O3 ceramic wafer membrane with a thickness of 250 mu m and the mean pore size of approximately 200 nm was prepared from the Al2O3/polysulfone slurries via a casting -phase inversion/sintering approach. This ultrathin and hydrophilic ceramic wafer has a fully sponge-like and slightly asymmetric structure and desirable porosity, endowing it with an exceptionally high pure water permeability of -45,000 L m -2h- 1 bar -1, an ultrahigh and stable emulsion flux of 2500 -3500 L m-2h-1 bar -1, as well as a high oil rejection of 99 % against real oilfield produced water (OPW). In addition, the increased Al2O3 content enhanced the thermodynamic instability of the ceramic slurry, leading to the enhanced interfacial instability, which contributes to the uniform distribution of Al2O3 particles on the precursor membrane surface to some extent during the phase inversion process, thus to reduce the surface defects of ceramic membranes after sintering. The membrane fouling analysis revealed that the dominant fouling mechanism was cake filtration, indicating the formation of a relatively dense and smooth skin layer of the ceramic wafer, which endow it with a high flux recovery ratio of 97.8 % by a simple chemical cleaning after OPW filtration.

Automated summary

Efficient preparation of ultrathin Al2O3 ceramic membranes with desirable porosity and hydrophilicity has been achieved by a casting-phase inversion/sintering approach. These membranes exhibit exceptionally high pure water permeability and stable emulsion flux, as well as high oil rejection against real oilfield produced water. The enhanced interfacial instability during the phase inversion process contributes to reduced surface defects, while cake filtration dominates the fouling mechanism, allowing for high flux recovery by chemical cleaning.