解决淡水稀缺和制氢问题:近海风能与反渗透技术的协同作用

IF 6.5 3区 材料科学 Q2 GREEN & SUSTAINABLE SCIENCE & TECHNOLOGY
Haris Ishaq, Curran Crawford
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引用次数: 0

摘要

为了减缓气候变化和实现可持续发展目标(SGDs),从化石燃料向可再生能源过渡势在必行。氢作为一种清洁能源载体,在各行各业的去碳化方面具有巨大潜力,但其生产仍然主要依赖化石燃料。本研究探索了一种将海上风能与反渗透(RO)海水淡化技术相结合的可持续制氢新方法。拟议的配置利用海上风能为反渗透海水淡化系统和水电解装置提供能量。首先,风能为反渗透海水淡化过程提供动力,净化海水,然后将淡化水引入水电解系统,直接从海水中产生绿色氢气。由此产生的可再生氢具有多种应用潜力,包括海洋工业,并可根据需要运输到岸上。反渗透系统的配置是处理 20 kg s-1 的海水,盐度为 35 000 ppm,目的是获得高回收率并降低淡水盐度。系统集成了一个压力交换器(PX),用于回收高压盐水流中的能量,并将其转移到低压进水中,从而降低反渗透工艺的总体能耗。从反渗透海水淡化过程中提取的浓盐水拟用于生产氢氧化钠,氢氧化钠可进一步预处理进入的海水,并通过减轻膜堵塞提高过滤过程的效率。该压力交换器可将反渗透系统的能效从 63.1% 提高到 64.0%,能效从 13.9% 提高到 18.2%,第一和第二定律总效率分别提高到 37.9% 和 33.5%。通过利用近海风能驱动反渗透海水淡化系统,这项研究不仅解决了淡水匮乏问题,还促进了绿色制氢,推动了可再生能源解决方案的发展,促进了环境的可持续发展。
本文章由计算机程序翻译,如有差异,请以英文原文为准。

Addressing Freshwater Scarcity and Hydrogen Production: Offshore Wind and Reverse Osmosis Synergies

Addressing Freshwater Scarcity and Hydrogen Production: Offshore Wind and Reverse Osmosis Synergies

Addressing Freshwater Scarcity and Hydrogen Production: Offshore Wind and Reverse Osmosis Synergies

The transition from fossil fuels to renewable energy sources is imperative to mitigate climate change and achieve sustainable development goals (SGDs). Hydrogen, as a clean energy carrier, holds great potential for decarbonizing various sectors, yet its production remains predominantly reliant on fossil fuels. This study explores a novel approach to sustainable hydrogen production by integrating offshore wind energy with reverse osmosis (RO) desalination technology. The proposed configuration harnesses offshore wind power to energize both a RO desalination system and water electrolysis unit. Initially, the wind energy powers the RO desalination process, purifying seawater, and then desalinated water is directed to water electrolysis system for generating green hydrogen directly from seawater. The resulting renewable hydrogen holds potential for diverse applications, including marine industries, and can be transported onshore as needed. The RO system is configured to treat 20 kg s−1 of seawater with a salinity of 35 000 ppm, aiming for a high recovery ratio and reduced freshwater salinity. A pressure exchanger (PX) is integrated to recover energy from high-pressure brine stream and transfer it to the low-pressure feed water, thus reducing the overall energy consumption of the RO process. The concentrated brine extracted from RO desalination is proposed to be utilized for the production of sodium hydroxide that can further pretreat incoming seawater and enhance the effectiveness of the filtration process by mitigating membrane fouling. This pressure exchanger increases the energy efficiency of the RO system from 63.1% to 64.0% and exergetic efficiency from 13.9% to 18.2% increasing the overall first and second law efficiencies to 37.9% and 33.5%. By leveraging offshore wind power to drive RO desalination systems, this research not only addresses freshwater scarcity but also facilitates green hydrogen generation, contributing to the advancement of renewable energy solutions and fostering environmental sustainability.

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来源期刊
Advanced Sustainable Systems
Advanced Sustainable Systems Environmental Science-General Environmental Science
CiteScore
10.80
自引率
4.20%
发文量
186
期刊介绍: Advanced Sustainable Systems, a part of the esteemed Advanced portfolio, serves as an interdisciplinary sustainability science journal. It focuses on impactful research in the advancement of sustainable, efficient, and less wasteful systems and technologies. Aligned with the UN's Sustainable Development Goals, the journal bridges knowledge gaps between fundamental research, implementation, and policy-making. Covering diverse topics such as climate change, food sustainability, environmental science, renewable energy, water, urban development, and socio-economic challenges, it contributes to the understanding and promotion of sustainable systems.
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