{"title":"Life Cycle Water Use for Oxy Fuel Combustion Power Generation with CO2 Capture and Storage","authors":"M. Jalal, Q. Yang, Chen Mengxi","doi":"10.12783/dteees/iceee2019/31758","DOIUrl":null,"url":null,"abstract":"The water scarcity is becoming a growing concern. Regarded as a potential CO emission mitigation technology for coal-fired power plants, oxy-fuel combustion, a typical CCS technology, theoretically consumes a large amount of water, which increases the severity of the water scarcity. Therefore, revealing the water use of oxy-fuel coal-fired power plants is of great importance for the deployment of CCS technologies under water resource constraint in the future. In this respect, the aim of this study is to evaluate the life cycle water use of oxy-fuel CO capture, transport and storage via a 600 MW coal fired oxy-fuel power plant in China. By using a tiered hybrid life cycle assessment, both direct and indirect water use are calculated. Results show 22.9L H O/kg of CO and the oxy-fuel power plant stage dominates the total water use, while the water intensity for power generation is calculated as 3233.3 L H O/MWh, which is higher than the conventional power plants. Sensitivity analysis is performed in this research and indicates that the variation of tap water use affects the water intensity immensely. Furthermore, the use of the membrane method for air separation decreases the overall water use 14.21% respectively. China is continually increasing its efforts to reduce carbon emissions due to both domestic and international pressure. Hence the development and implement of the CCS technology is of great urgency. At the end of this study possible solutions such as using wasted or discarded wind power for the separation of oxygen to minimize water use in oxy-fuel power plant stage are put forward.","PeriodicalId":11324,"journal":{"name":"DEStech Transactions on Environment, Energy and Earth Sciences","volume":"1 1","pages":""},"PeriodicalIF":0.0000,"publicationDate":"2019-10-31","publicationTypes":"Journal Article","fieldsOfStudy":null,"isOpenAccess":false,"openAccessPdf":"","citationCount":"0","resultStr":null,"platform":"Semanticscholar","paperid":null,"PeriodicalName":"DEStech Transactions on Environment, Energy and Earth Sciences","FirstCategoryId":"1085","ListUrlMain":"https://doi.org/10.12783/dteees/iceee2019/31758","RegionNum":0,"RegionCategory":null,"ArticlePicture":[],"TitleCN":null,"AbstractTextCN":null,"PMCID":null,"EPubDate":"","PubModel":"","JCR":"","JCRName":"","Score":null,"Total":0}
引用次数: 0
Abstract
The water scarcity is becoming a growing concern. Regarded as a potential CO emission mitigation technology for coal-fired power plants, oxy-fuel combustion, a typical CCS technology, theoretically consumes a large amount of water, which increases the severity of the water scarcity. Therefore, revealing the water use of oxy-fuel coal-fired power plants is of great importance for the deployment of CCS technologies under water resource constraint in the future. In this respect, the aim of this study is to evaluate the life cycle water use of oxy-fuel CO capture, transport and storage via a 600 MW coal fired oxy-fuel power plant in China. By using a tiered hybrid life cycle assessment, both direct and indirect water use are calculated. Results show 22.9L H O/kg of CO and the oxy-fuel power plant stage dominates the total water use, while the water intensity for power generation is calculated as 3233.3 L H O/MWh, which is higher than the conventional power plants. Sensitivity analysis is performed in this research and indicates that the variation of tap water use affects the water intensity immensely. Furthermore, the use of the membrane method for air separation decreases the overall water use 14.21% respectively. China is continually increasing its efforts to reduce carbon emissions due to both domestic and international pressure. Hence the development and implement of the CCS technology is of great urgency. At the end of this study possible solutions such as using wasted or discarded wind power for the separation of oxygen to minimize water use in oxy-fuel power plant stage are put forward.
水资源短缺正成为一个日益令人担忧的问题。全氧燃烧作为典型的CCS技术,在理论上消耗大量的水,增加了水资源短缺的严重程度,被认为是一种有潜力的燃煤电厂CO减排技术。因此,揭示全氧燃煤电厂的用水情况,对于未来水资源约束下CCS技术的部署具有重要意义。在这方面,本研究的目的是通过中国一座600兆瓦的燃煤全氧电厂来评估全氧燃料CO捕集、运输和储存的生命周期用水量。通过分层混合生命周期评估,计算了直接和间接用水量。结果表明:CO为22.9L H O/kg,全氧火力发电厂阶段占总用水量的主导地位,发电用水强度为3233.3 L H O/MWh,高于常规火力发电厂;本研究进行了敏感性分析,结果表明自来水用量的变化对水强度的影响很大。此外,采用膜法进行空气分离的总用水量分别降低了14.21%。由于国内和国际的压力,中国正在不断加大减少碳排放的努力。因此,开发和实施CCS技术刻不容缓。在本研究的最后,提出了可能的解决方案,如利用废弃或废弃的风力发电进行氧分离,以尽量减少氧燃料发电厂阶段的用水量。