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Synthesis and characterization of <scp>PVC‐TFC</scp> hollow fibers for forward osmosis application

Wafaa Kh. Al‐Musawy, Mustafa H. Al‐Furaiji, Qusay F. Alsalhy

2021Journal of Applied Polymer Science16 citationsDOI

Abstract

Abstract Forward osmosis (FO) is considered among the most encouraging water desalination processes as a result of its high performance and low energy demand. Thin‐film composite (TFC) hollow fibers (HF) were synthesized and examined in the FO process. Three different concentrations of polyvinyl chloride (PVC) support polymer were fabricated via the phase inversion technique. The polyamide layer was synthesized on the outer surface of the PVC‐HF substrate via interfacial polymerization (IP) reaction. To the best of our knowledge, PVC HF was used in this research for the first time as a support for TFC‐FO membranes. PVC HFs have high‐quality specifications that are expected to have outstanding performance in TFC‐FO applications, especially for water desalination. The obtained membranes were characterized using contact angle measurement, scanning electron microscopy, atomic force microscope and Fourier‐transform Infrared. The performance of the PVC‐TFC HF was examined in the FO under standard conditions. Results showed that the membrane fabricated with a lower concentration of PVC substrate exhibited higher water flux in comparison to the higher concentration PVC membrane. Changing the concentration of PVC from 15% to 18% reduced water flux from 25 to 13 L m −2 h −1 ; however, salt flux also decreased from 8 to 3 g m −2 h −1 .

Topics & Concepts

Thin-film composite membraneInterfacial polymerizationForward osmosisMembraneMaterials sciencePolyvinyl chlorideChemical engineeringPhase inversionScanning electron microscopeDesalinationPolyamideContact anglePolymerFourier transform infrared spectroscopyReverse osmosisPressure-retarded osmosisSubstrate (aquarium)Polymer chemistryComposite materialChemistryOceanographyBiochemistryMonomerGeologyEngineeringMembrane Separation TechnologiesHigh voltage insulation and dielectric phenomenaMembrane-based Ion Separation Techniques