天然气凝析液稳定及加热减压脱除CO2的动态稳态模拟研究

IF 2.8 Q2 ENGINEERING, CHEMICAL
Mohsin Ehsan, Usman Ali, Farooq Sher, Hafiz M. Abubakar, Muhammad Fazal Ul Basit
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引用次数: 0

摘要

与其他油气工艺相比,凝析油的稳定是一个高能耗的过程。有必要减少这种能源消耗。因此,目前的工作旨在模拟稳定装置的可用能量和符合规格的稳定凝析油产品。天然气凝析液(NGL)在被送往炼油厂之前,需要通过消除较轻的碳氢化合物气体和酸性气体来稳定。稳定NGL的蒸汽压测定为7 psia的Reid蒸汽压,表明轻组分没有作为单独的气相演化。通过Aspen HYSYS进行稳态和动态模拟,通过加热和减压的蒸馏方法进行稳定化和CO2脱除。根据稳定和CO2去除过程可用的工具,对交换器和塔周围的不同工艺进行了研究。通过灵敏度研究,包括CO2浓度的影响、稳定器闪蒸分离器入口温度的影响以及PID控制器的动态仿真,分析了其对过程参数的影响,如运行空气冷却器的Reid蒸气压(RVP)和CO2以及交换器的热负荷。实际工厂数据已用于验证过程模拟值,以确保凝析液稳定装置模型的准确性。根据分析的情景,可以得出结论,氮气汽提法在冷却器出口的冷凝水中获得了7 ppmv CO2和7 psia RVP,而在所有情景中观察到的稳定冷凝水流量变化为29桶/天,数据验证显示Aspen Hysys数据与实际工厂数据之间存在0.24%的差异。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
Dynamic and Steady-State Simulation Study for the Stabilization of Natural Gas Condensate and CO2 Removal through Heating and Pressure Reduction
Stabilization of condensate is a highly energy-consuming process compared to other oil and gas processes. There is a need to reduce this energy consumption. Therefore, the present work aims to simulate the stabilization unit in terms of available energy and on-spec stabilized condensate products. Natural gas condensate liquids (NGL) need to be stabilized by eliminating lighter hydrocarbon gases and acid gases before being sent to the refinery. Stabilized NGL has the vapor pressure determined as a Reid vapor pressure of 7 psia, showing that light components did not evolve as a separate gas phase. Stabilization and CO2 removal was performed through the distillation method by heating and pressure reduction using steady state and dynamic simulation through Aspen HYSYS. Different process alterations around the exchanger and column have been studied based on the utilities available for the stabilization and CO2 removal process. Sensitivity studies, including the impact of CO2 concentration, the temperature at the inlet of the stabilizer flash separator, and the dynamic simulation for the PID controller, have been performed to analyze the impact on the process parameters, such as Reid vapor pressure (RVP) and CO2 of the rundown air cooler and heat duties of the exchangers. Actual plant data have been used for the validation of process simulation values for the accuracy of the condensate stabilization unit model. Based on the scenarios analyzed, it can be concluded that the nitrogen stripping method achieved 7 ppmv CO2 and 7 psia RVP in the condensate from the cooler outlet, while a variation of 29 bpd was observed for the stabilized condensate flowrate throughout all scenarios with data validation showing 0.24% discrepancy between Aspen Hysys data and actual plant data.
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来源期刊
ChemEngineering
ChemEngineering Engineering-Engineering (all)
CiteScore
4.00
自引率
4.00%
发文量
88
审稿时长
11 weeks
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