Gravity-driven highly selective ultrafiltration: a sustainable solution for addressing global drinking water scarcity

IF 4.9 3区工程技术 Q1 ENGINEERING, CHEMICAL

Reviews in Chemical Engineering Pub Date : 2025-06-28 DOI:10.1515/revce-2024-0040

I Gede Wenten, Khoiruddin Khoiruddin

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引用次数: 0

Abstract

This review explores the potential of gravity-driven ultrafiltration (GDU) systems as a sustainable solution to global drinking water challenges. Leveraging hydrostatic pressure instead of external energy inputs, GDU systems offer a low-maintenance, cost-effective approach well-suited for decentralized and resource-constrained settings. The paper provides a detailed analysis of the fluid dynamics and transport mechanisms that underpin GDU operation, emphasizing the influence of biofilm formation, membrane morphology, and material selectivity on system performance. Recent advancements in membrane materials have demonstrated significant improvements in antifouling performance, flux stability, and contaminant removal. Innovative membrane designs are also reviewed for their potential to enhance adaptability and multifunctionality. Real-world case studies highlight the operational feasibility and economic advantages of GDU systems, while identifying key barriers such as long-term reliability, feedwater variability, and limited community-based monitoring capacity. Socio-economic considerations, including modular design strategies and institutional engagement, are examined to support scalable implementation. This comprehensive review offers interdisciplinary insights to inform future research, technology development, and policy planning aimed at advancing sustainable water purification solutions worldwide.

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重力驱动的高选择性超滤：解决全球饮用水短缺的可持续解决方案

本综述探讨了重力驱动超滤（GDU）系统作为全球饮用水挑战的可持续解决方案的潜力。利用静水压力代替外部能源输入，GDU系统提供了一种低维护、低成本的方法，非常适合分散和资源有限的环境。本文详细分析了支撑GDU运行的流体动力学和传输机制，强调了生物膜形成、膜形态和材料选择对系统性能的影响。近年来，膜材料在防污性能、通量稳定性和污染物去除方面取得了重大进展。创新的膜设计也回顾了其增强适应性和多功能性的潜力。实际案例研究强调了GDU系统的运营可行性和经济优势，同时确定了长期可靠性、给水可变性和有限的社区监测能力等关键障碍。社会经济方面的考虑，包括模块化设计策略和机构参与，进行了审查，以支持可扩展的实施。这篇综合综述为未来的研究、技术开发和政策规划提供了跨学科的见解，旨在推动全球可持续的水净化解决方案。

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

Reviews in Chemical Engineering 工程技术-工程：化工

CiteScore

12.30

自引率

0.00%

发文量

审稿时长

6 months

期刊介绍： Reviews in Chemical Engineering publishes authoritative review articles on all aspects of the broad field of chemical engineering and applied chemistry. Its aim is to develop new insights and understanding and to promote interest and research activity in chemical engineering, as well as the application of new developments in these areas. The bimonthly journal publishes peer-reviewed articles by leading chemical engineers, applied scientists and mathematicians. The broad interest today in solutions through chemistry to some of the world’s most challenging problems ensures that Reviews in Chemical Engineering will play a significant role in the growth of the field as a whole.