Process optimization of osmotic membrane distillation for the extraction of valuable resources from water streams

IF 10.4 1区 工程技术 Q1 ENGINEERING, CHEMICAL npj Clean Water Pub Date : 2024-01-02 DOI:10.1038/s41545-023-00294-2
Matteo Morciano, Marco Malaguti, Francesco Ricceri, Alberto Tiraferri, Matteo Fasano
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Abstract

The rising demand for sustainable wastewater management and high-value resource recovery is pressing industries involved in, e.g., textiles, metals, and food production, to adopt energy-efficient and flexible liquid separation methods. The current techniques often fall short in achieving zero liquid discharge and enhancing socio-economic growth sustainably. Osmotic membrane distillation (OMD) has emerged as a low-temperature separation process designed to concentrate valuable elements and substances in dilute feed streams. The efficacy of OMD hinges on the solvent’s migration from the feed to the draw stream through a hydrophobic membrane, driven by the vapor pressure difference induced by both temperature and concentration gradients. However, the intricate interplay of heat and mass processes steering this mechanism is not yet fully comprehended or accurately modeled. In this research, we conducted a combined theoretical and experimental study to explore the capabilities and thermodynamic limitations of OMD. Under diverse operating conditions, the experimental campaign aimed to corroborate our theoretical assertions. We derived a novel equation to govern water flux based on foundational principles and introduced a streamlined version for more straightforward application. Our findings spotlight complex transport-limiting and self-adjusting mechanisms linked with temperature and concentration polarization phenomena. Compared with traditional methods like membrane distillation and osmotic dilution, which are driven by solely temperature or concentration gradients, OMD may provide improved and flexible performance in target applications. For instance, we show that OMD—if properly optimized—can achieve water vapor fluxes 50% higher than osmotic dilution. Notably, OMD operation at reduced feed temperatures can lead to energy savings ranging between 5 and 95%, owing to the use of highly concentrated draw solutions. This study underscores the potential of OMD in real-world applications, such as concentrating lithium in wastewater streams. By enhancing our fundamental understanding of OMD’s potential and constraints, we aim to broaden its adoption as a pivotal liquid separation tool, with focus on sustainable resource recovery.

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从水流中提取宝贵资源的渗透膜蒸馏工艺优化
对可持续废水管理和高价值资源回收的需求不断增长,迫使纺织、金属和食品生产等行业采用节能、灵活的液体分离方法。目前的技术往往无法实现液体零排放和可持续地促进社会经济增长。渗透膜蒸馏(OMD)是一种低温分离工艺,旨在浓缩稀料流中有价值的元素和物质。OMD 的功效取决于溶剂在温度和浓度梯度引起的蒸汽压力差的驱动下,通过疏水膜从进料流迁移到出料流。然而,人们尚未完全理解或准确模拟指导这一机制的热量和质量过程之间错综复杂的相互作用。在这项研究中,我们开展了一项理论与实验相结合的研究,以探索 OMD 的能力和热力学限制。在不同的操作条件下,实验活动旨在证实我们的理论论断。我们在基本原理的基础上推导出一个新方程来控制水流量,并推出了一个简化版本,以便更直接地应用。我们的研究结果揭示了与温度和浓度极化现象相关的复杂传输限制和自我调整机制。与仅由温度或浓度梯度驱动的膜蒸馏和渗透稀释等传统方法相比,OMD 可在目标应用中提供更好的灵活性能。例如,我们的研究表明,如果经过适当优化,OMD 的水蒸气通量可比渗透稀释法高出 50%。值得注意的是,由于使用了高浓度的汲取溶液,OMD 在较低的进料温度下运行可节省 5% 到 95% 的能源。这项研究强调了 OMD 在实际应用中的潜力,例如浓缩废水中的锂。通过加强我们对 OMD 的潜力和限制因素的基本了解,我们旨在扩大其作为关键液体分离工具的应用范围,重点关注可持续资源回收。
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来源期刊
npj Clean Water
npj Clean Water Environmental Science-Water Science and Technology
CiteScore
15.30
自引率
2.60%
发文量
61
审稿时长
5 weeks
期刊介绍: npj Clean Water publishes high-quality papers that report cutting-edge science, technology, applications, policies, and societal issues contributing to a more sustainable supply of clean water. The journal's publications may also support and accelerate the achievement of Sustainable Development Goal 6, which focuses on clean water and sanitation.
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