In this paper, the concept of the functional mechanism of copolymer membrane formation is explained and analyzed from the theoretical and experimental points of view. To understand the phase inversion process and control the final membrane morphology, styrene-acrylonitrile copolymer (SAN) membrane morphology through the self-assembly phenomena is investigated. Since the analysis of the membrane morphology requires the study of both thermodynamic and kinetic parameters, the effect of different membrane formation conditions is investigated experimentally; In order to perceive the formation mechanism of the extraordinary structure membrane, a thermodynamic hypothesis is also developed based on the hydrophilic coil migration to the membrane surface. This hypothesis is analyzed according to Hansen Solubility Parameters and proved using EDX, SAXS, and contact angle analysis of SAN25. Moreover, the SAN30 membrane is fabricated under different operating conditions to evaluate the possibility of morphological prediction based on the developed hypothesis.
The microfiltration membrane separation process in oil effluent treatment was investigated experimentally. The flux of poly(styrene‐co‐acrylonitrile) with 25 wt % (SAN25) and 30 wt % (SAN30) of acrylonitrile fraction using different solvents in two different feed types (distilled water and 5000 mg L−1 stabilized oil‐in‐water (O/W) emulsion) was studied. In the case of the O/W emulsion, the performance of the membranes was evaluated using oil rejection. The chemical oxygen demand test was used to analyze the oil concentration in the permeate and to calculate the rejection. The results show a decline in the O/W treatment flux in comparison with the distilled water. The water permeate of SAN25 using dimethylformamide and N‐methyl‐2‐pyrrolidone was 200 and 170 L m−2h−1, respectively, and permeate flux values of 290 and 210 L m−2h−1 were obtained using SAN30.
In this paper, the concept of functional mechanism of copolymer membrane formation is explained and analyzed from theoretical and experimental point of view. To understand the phase inversion process and control the final membrane morphology, styrene-acrylonitrile copolymer (SAN) membrane morphology through the self-assembly phenomena is investigated. Since the analysis of the membrane morphology requires the study of both thermodynamic and kinetic parameters, the effect of different membrane formation conditions is investigated experimentally; In order to perceive the formation mechanism of the extraordinary structure membrane, a thermodynamic hypothesis is also developed based on the hydrophilic coil migration to the membrane surface. This hypothesis is analyzed according to Hansen Solubility Parameters and proved using EDX, SAXS and contact angle analysis of SAN25. Moreover, the SAN30 membrane is fabricated under different operating conditions to evaluate the possibility of morphological prediction based on the developed hypothesis.
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