A A Novel Poly (vinylidene) Fluoride/TiO2/Spent Bleaching Earth for Enhancing Hydrophilic Hollow Fibre Membrane

Q2 Mathematics
Rhafiq Abdul Ghani, Muthia Elma, Aulia Rahma, Zahratun Nisa
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Abstract

Nowadays, polymer as the raw material has been utilized in the development of Hollow Fibre (HF) membranes. PVDF is a commonly used for HF membrane material. However, it has hydrophobicity properties and lead membrane becomes low permeability and fouling. Therefore, to avoid these membranes problems, the incorporation of inorganic nanoparticles into PVDF membranes matrix is necessary to be applied for significantly improving PVDF membranes performance. This study investigates the characteristics and performance of PVDF-TiO2 HF membranes using spent bleaching earth (SBE) as a promising material from industrial waste as a renewable inorganic nanoparticle. This novel PVDF-TiO2-SBE HF membrane was fabricated using the subsequent steps: The preparation process incorporates SBE revival through solvent extraction and thermal treatment alongside the wet spinning technique for membrane fabrication. The Fourier transform infrared (FTIR) functional groups, scanning electron microscope (SEM) morphology, water contact angle and pure water flux performance were investigated to specifically understand the performance of this typical HF membranes. The IR results show that Si-O-Si groups were found in the membrane matrices due to the addition of SBE material. The addition of TiO2-SBE particles also indicate a sandwich (sponge-finger-like) morphological structure on the cross-sectional, a rough and porous surface structures. The hydrophilic properties of the HF membrane and pure water flux performance are determined by the composition of the TiO2-SBE mixture added as an additive material. The minimum contact angle found at 74.33°, while the water flux is 5.81 kg.m-2.h-1 on the identical HF membrane. Accordingly, this approach significantly enhances the properties of the pure PVDF HF membrane.
用于增强亲水性中空纤维膜的新型聚偏氟乙烯/二氧化钛/五氯漂白土
如今,聚合物作为原材料已被用于中空纤维(HF)膜的开发。PVDF 是一种常用的高频膜材料。然而,它具有疏水性,会导致膜渗透性低和结垢。因此,为了避免这些膜问题,有必要在 PVDF 膜基质中加入无机纳米粒子,以显著提高 PVDF 膜的性能。本研究利用从工业废料中提取的废漂白土(SBE)作为可再生无机纳米粒子,研究了 PVDF-TiO2 高频膜的特性和性能。这种新型 PVDF-TiO2-SBE 高频膜是通过后续步骤制成的:在制备过程中,通过溶剂萃取和热处理使 SBE 重生,同时采用湿法纺丝技术制备膜。通过对傅立叶变换红外(FTIR)官能团、扫描电子显微镜(SEM)形貌、水接触角和纯水通量性能的研究,具体了解了这种典型高频膜的性能。红外结果表明,由于添加了 SBE 材料,膜基质中发现了 Si-O-Si 基团。此外,TiO2-SBE 颗粒的加入还显示出横截面上的三明治(海绵指状)形态结构、粗糙和多孔的表面结构。高频膜的亲水性能和纯水通量性能取决于作为添加剂添加的 TiO2-SBE 混合物的成分。在相同的高频膜上,最小接触角为 74.33°,而水通量为 5.81 kg.m-2.h-1。因此,这种方法大大提高了纯 PVDF 高频膜的性能。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
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来源期刊
CFD Letters
CFD Letters Chemical Engineering-Fluid Flow and Transfer Processes
CiteScore
3.40
自引率
0.00%
发文量
76
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