Growing desalination capacity worldwide has made management of discharge brines an increasingly urgent environmental challenge. An important step in understanding how to choose between different brine management processes is to study the energetics of these processes. In this paper, we analyze two different ways of managing highly saline brines. The first method is complete separation with production of salts (i.e., zero-discharge desalination or ZDD). Thermodynamic limits of the ZDD process were calculated. This result was applied to the state-of-the-art industrial ZDD process to quantify how close these systems are to the thermodynamic limit, and to compare the energy consumption of the brine concentration step to the crystallization step. We conclude that the brine concentration step has more potential for improvement compared to the crystallization step. The second brine management method considered is salinity-gradient power generation through pressure-retarded osmosis (PRO), which utilizes the brine's high concentration to produce useful work while reducing its concentration by mixing the brine with a lower salinity stream in a controlled manner. We model the PRO system coupled with a desalination system using a detailed numerical optimization, which resulted in about 0.42 kW h/m3 of energy saving.
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机译:全球范围内海水淡化能力的不断提高使排放盐水的管理成为日益迫切的环境挑战。理解如何在不同盐水管理过程之间进行选择的重要步骤是研究这些过程的能量。在本文中,我们分析了两种处理高盐度盐水的不同方法。第一种方法是完全分离并产生盐(即零排放脱盐或ZDD)。计算了ZDD过程的热力学极限。此结果已应用于最新的工业ZDD工艺中,以量化这些系统与热力学极限的接近程度,并比较盐水浓缩步骤和结晶步骤的能耗。我们得出的结论是,与结晶步骤相比,盐水浓缩步骤具有更大的改进潜力。考虑的第二种盐水管理方法是通过压力延迟渗透(PRO)进行盐度梯度发电,该方法利用盐水的高浓度来产生有用的功,同时通过以受控方式将盐水与较低盐度的流混合来降低其浓度。我们使用详细的数值优化对PRO系统与脱盐系统进行了建模,从而节省了约0.42 kW h / m3的能源。
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