Optimum chain desalination process design for treatment of high TDS brine: A case assessment for future treatment of extracted brine from Shenhua CO2 storage site

IF 2.7 4区 环境科学与生态学 Q3 ENERGY & FUELS
Hesam Bazargan Harandi, Liwei Zhang, Ali Kargari, Pang-Chieh Sui, Yan Wang, Meiheriayi Mutailipu, Hao Lu, Qi Li
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引用次数: 0

Abstract

Carbon dioxide-enhanced water recovery (CO2-EWR) is a promising strategy for managing reservoir pressure build-up and mitigating the risk of fault activation resulting from CO2 injection in deep saline aquifers. CO2-EWR can also be employed for supplying the required water for different applications after a treatment stage for the produced saline water. In this study, a brief review on CO2-EWR technology and its necessities are first carried out. After that, the feasibilities, advantages, and challenges of various available treatment technologies that can potentially be used to treat high total dissolved solids (TDS) brine are comprehensively assessed. Based on comprehensive evaluation on technologies, a chain desalination process, consisting of pretreatment, main treatment, and post treatment, is proposed as a strategic path for the treatment of high TDS brine extracted from the Shenhua CCS site. It is concluded that coagulation-flocculation and gravity filtration are needed as primary stages to remove suspended particles, while membrane distillation (MD) is selected as a suitable main treatment technology for high TDS Shenhua brine. Then, MD treatment is comprehensively discussed for a small-scale treatment of extracted Shenhua brine assuming that the pretreated brine is free of suspended solids. After presenting the heat and mass transfer equations for direct contact membrane distillation (DCMD), a mathematical thermodynamic model is programmed in EES (Engineering Equation Solver) software to briefly analyze the performance parameters of DCMD. The results indicate that the designed DCMD, in the absence of auxiliary systems and considering the inherent temperature of extracted brine from different formations, has the capability of producing 15.1 kg m−2hr of freshwater from the extracted brine of the Shihezi formation layer. In the case of employing the auxiliary system of flat-plate collector (FPC) combined with heat exchanger (HX) to heat up the extracted Shenhua brine to the desired temperature of 80°C, the amounts of produced flux are enhanced by 133%, 72%, and 45% for the brine extracted from Liujiagou, Shiqianfeng, and Shihezi formations, respectively. Using the yearly solar radiation model in TRNSYS software, the maximum solar radiation on the tilted surface at the location of Shenhua project in Inner Mongolia Autonomous Region of China reaches 3800 kJ m−2hr at 1 PM on April 1. Considering maximum solar radiation on the tilted surface, it is proved that a small-surface FPC can supply the required energy to heat up the extracted brine from its inherent temperature to the desired temperature of 80°C. © 2023 Society of Chemical Industry and John Wiley & Sons, Ltd.

处理高TDS卤水的链式脱盐工艺优化设计——以神华CO2储存场提取卤水未来处理为例
二氧化碳增水采收率(CO2- ewr)是一种很有前途的策略,可以控制储层压力积聚,降低深层盐水含水层中二氧化碳注入导致断层活化的风险。CO2-EWR也可用于在对产出的咸水进行处理阶段后为不同应用提供所需的水。本文首先对CO2-EWR技术及其必要性进行了简要的综述。在此基础上,对各种可用于处理高总溶解固体(TDS)盐水的现有处理技术的可行性、优势和挑战进行了综合评估。在技术综合评价的基础上,提出了由预处理、主处理、后处理组成的链式海水淡化工艺,作为处理神华CCS场址高TDS盐水的战略路径。结果表明,混凝-絮凝和重力过滤是去除悬浮颗粒的初级阶段,膜蒸馏是处理高TDS神华盐水的主要工艺。然后,在预处理盐水不含悬浮物的前提下,对神华萃取盐水的小规模处理进行了MD处理。在建立了直接接触膜蒸馏(DCMD)的传热传质方程的基础上,利用工程方程求解器(EES)编制了数学热力学模型,对DCMD的性能参数进行了简要分析。结果表明,在没有辅助系统的情况下,考虑不同地层抽提盐水固有温度,所设计的DCMD能够从石河子地层抽提盐水中生产15.1 kg m−2hr的淡水。采用平板集热器(FPC)联合换热器(HX)辅助系统将抽取的神华卤水加热至所需温度80℃时,刘家沟、石千峰、石河子三层抽取的卤水分别提高了133%、72%和45%的产通量。利用TRNSYS软件的年太阳辐射模式,在4月1日下午1时,中国内蒙古神华工程所在倾斜地表的最大太阳辐射达到3800 kJ m−2hr。考虑倾斜表面的最大太阳辐射,证明了小表面FPC可以提供所需的能量,将提取的盐水从其固有温度加热到所需的80℃温度。©2023化学工业协会和John Wiley &儿子,有限公司
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来源期刊
Greenhouse Gases: Science and Technology
Greenhouse Gases: Science and Technology ENERGY & FUELS-ENGINEERING, ENVIRONMENTAL
CiteScore
4.90
自引率
4.50%
发文量
55
审稿时长
3 months
期刊介绍: Greenhouse Gases: Science and Technology is a new online-only scientific journal dedicated to the management of greenhouse gases. The journal will focus on methods for carbon capture and storage (CCS), as well as utilization of carbon dioxide (CO2) as a feedstock for fuels and chemicals. GHG will also provide insight into strategies to mitigate emissions of other greenhouse gases. Significant advances will be explored in critical reviews, commentary articles and short communications of broad interest. In addition, the journal will offer analyses of relevant economic and political issues, industry developments and case studies. Greenhouse Gases: Science and Technology is an exciting new online-only journal published as a co-operative venture of the SCI (Society of Chemical Industry) and John Wiley & Sons, Ltd
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