2024 年水与能源关系中的膜淡化技术路线图

Antonio Politano, Raed A. Al-Juboori, Sultan Alnajdi, A. Alsaati, A. Athanassiou, Maya Bar-Sadan, Ali Naderi Beni, Davide Campi, A. Cupolillo, Gianluca D’Olimpio, Giuseppe D'Andrea, Humberto Estay, D. Fragouli, L. Gurreri, Norredine Ghaffour, Jack Gilron, Nidal Hilal, Jessica Occhiuzzi, Mateo Roldan Carvajal, Avner Ronen, Sergio Santoro, Michele Tedesco, R. A. Tufa, Mathias Ulbricht, D. Warsinger, D. Xevgenos, Guillermo Zaragoza, Yong-Wei Zhang, Ming Zhou, E. Curcio
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引用次数: 0

摘要

水和能源是可持续发展的两大战略驱动力,两者紧密相连,对人类未来的安全至关重要。鉴于水资源有限,而全球人口和能源需求却呈指数级增长,这些资源之间的竞争平衡,即所谓的水与能源的关系,正重新受到人们的关注。海水淡化行业通过从海水、咸水或地下水等含盐资源中生产淡水来缓解水资源压力。自过去十年以来,膜法海水淡化技术一直在市场上占据主导地位,与热法工艺相比,膜法海水淡化技术具有明显的优势,如能源需求低、工艺控制和放大容易、模块化生产灵活、不同膜操作的协同整合可行等。可持续开采海水浓缩物这一令人兴奋的新领域,正在加速出现大量创新的膜材料和方法,用于盐水脱水和微量离子的选择性提取,尽管在可靠的商业应用方面存在成本可行性这一达摩克利斯之剑。另一方面,在几项新兴技术中,反向电渗析(SGP-RED)已被证明能够将河水、苦咸水和海水之间的化学势差转化为电能,至少在千瓦级规模上是如此。目前正在努力开发下一代离子交换膜,使其具有高过电选择性(特别是对单价离子)和低电阻,改进系统工程和优化运行条件,以实现提高迄今可达到的低功率密度(每平方米几瓦)的目标。本路线图采用一系列简短文稿的形式,由该领域的全球专家独立撰写。总体而言,这些文章全面介绍了水与能源之间的膜科学技术的现状,以及未来的发展方向。
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2024 Roadmap on membrane desalination technology at the water-energy nexus
Water and energy are two strategic drivers of sustainable development, intimately interlaced and vital for a secure future of humanity. Given that water resources are limited, whereas global population and energy demand are exponentially growing, the competitive balance between these resources, referred to as the water-energy nexus – is receiving renewed focus. The desalination industry alleviates water stress by producing freshwater from saline sources, such as seawater, brackish or groundwater. Since the last decade, the market has been dominated by membrane desalination technology, offering significative advantages over thermal processes, such as lower energy demand, easy process control and scale-up, modularity for flexible productivity, and feasibility of synergic integration of different membrane operations. The exciting new frontier of sustainable mining of seawater concentrates is accelerating the appearance of a plethora of innovative membrane materials and methods for brine dehydration and selective extraction of trace ions, although under the sword of Damocles represented by cost feasibility for reliable commercial application. On the other hand, among several emerging technologies, reverse electrodialysis (SGP-RED) was already proven capable – at least at the kW scale–of turning the chemical potential difference between river water, brackish water, and seawater into electrical energy. Efforts to develop a next generation of Ion Exchange Membranes exhibiting high perm-selectivity (especially toward monovalent ions) and low electrical resistance, to improve system engineering and to optimize operational conditions, pursue the goal of enhancing the low power density so far achievable (in the order of a few W per m2). This Roadmap takes the form of a series of short contributions written independently by worldwide experts in the topic. Collectively, such contributions provide a comprehensive picture of the current state of the art in membrane science and technology at the water-energy nexus, and how it is expected to develop in the future
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