通过HNGLRP CC&S技术减少碳排放

Sultan Ahmari, Abdullatef Mufti
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引用次数: 0

摘要

本文的目的是介绍沙特阿美天然气业务在最新的碳捕获与封存(CC&S)技术成功运行和可维护性之后,在减少Hawyiah NGL回收厂(HNGLRP)的碳排放方面取得的成功。这符合沙特阿拉伯王国(KSA) 2030年的愿景,即提高未来增长的资源可持续性,以及沙特阿美循环经济的一部分行动实例。沙特阿美公司的CC&S项目于2015年6月在HNGLRP启动,主要目的是捕获来自酸性气体去除装置(AGRUs)的二氧化碳(CO2),然后每年向油井注入近750万吨二氧化碳,用于封存和提高石油采收率的可维护性。这是为了取代AGRUs运行后典型的酸性气体焚烧工艺,以减少碳足迹。CC&S由以下部分组成:整体减速多级压缩机,独立脱水系统,使用三乙二醇(TEG),二氧化碳蒸汽回收装置(VRU),颗粒活性炭(GAC)处理压缩和脱水系统产生的水以供重复使用,以及特殊的浓相泵,通过85公里的管道将超临界阶段的脱水二氧化碳输送,以取代传统的海水注入方法,提高石油采收率。CC&S拥有以压缩机容量、超临界相流体泵送、利用机械喷射器最大限度地回收碳、CO2/TEG脱水系统作为非典型脱水系统等为代表的新技术和经验。CC&S设计考虑了压缩机运行过程中产生的职业健康危害,安装了工程围护结构,并配以适当的通风系统,将噪声危害降至最低。CC&S帮助HNGLRP减少了典型的二氧化碳焚烧过程(热氧化)产生的温室气体(GHG)排放。(2)自CC&S技术投入运行以来,HNGLRP燃烧源排放的温室气体总量减少了近30%。在AGRUs中运行热氧化剂的燃料用气量减少了75%,并作为销售用气发送。自2015年以来,能源强度指数(EII)下降了8%,水再利用指数(WRI)上升了12%。综上所述,该项目碳排放显著减少,产量显著提高,水回用效果显著。
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Carbon Emission Reduction via HNGLRP CC&S Technology
The paper objective is to present the successful achievement by Saudi Aramco gas operations to reduce the carbon emission at Hawyiah NGL Recovery Plant (HNGLRP) after successful operation & maintainability of the newly state of the art Carbon Capture & Sequestration (CC&S) technology. This is in line with the Kingdom of Saudi Arabia (KSA) 2030 vision to increase the resources sustainability for future growth and part of Saudi Aramco circular economy in action examples. Saudi Aramco CC&S started in June 2015 at HNGLRP with main objective to capture the carbon dioxide (CO2) from Acid Gas Removal Units (AGRUs) and then inject an annual mass of nearly 750 Kton of carbon dioxide into oil wells for sequestration and enhanced oil recovery maintainability. This is to replace the typical acid gas incineration process after AGRUs operation to reduce carbon footprint. CC&S consists of the followings: integrally geared multistage compressor, standalone dehydration system using Tri-Ethylene Glycol (TEG), CO2 vapor recovery unit (VRU), Granulated Activated Carbon (GAC) to treat water generated from compression and dehydration systems for reuse purpose, and special dense phase pump that transfers the dehydrated CO2 at supercritical phase through 85 km pipeline to replace the typical sea water injection methodology in enhancing oil recovery. CC&S has several new technologies and experiences represented by the compressor capacity, supercritical phase fluid pumping, using mechanical ejector application to maximize carbon recovery, and CO2/TEG dehydration system as non-typical dehydration system. CC&S design considered the occupational health hazards generated from the compressor operation by installing engineering enclosure with proper ventilation system to minimize the noise hazard. CC&S helped HNGLRP to reduce the overall Greenhouse Gas (GHG) emission resulted from typical CO2 incineration process (thermal oxidizing). (2) The total GHG resulted from combustion sources at HNGLRP reduced by nearly 30% since CC&S technology in operation. The fuel gas consumption to run the thermal oxidizers in AGRUs reduced by 75% and sent as sales gas instead. The Energy Intensity Index (EII) reduced by 8% since 2015, water reuse index (WRI) increased by 12%. In conclusion, the project shows significant reduction in the carbon emission, noticeable increase in the production, and considerable water reuse.
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