Chemical Industry and Engineering Progress ›› 2017, Vol. 36 ›› Issue (10): 3682-3689.DOI: 10.16085/j.issn.1000-6613.2016-2109

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Exergy analysis for the coal-based polygeneration system of FT syncrudes-power with CO2 capture

YU Gewen, WANG Yanming, YANG Xiaoli, WU Gangqiang   

  1. Chemistry and Chemical Engineering School, Inner Mongolia University of Science, Baotou 014010, Inner Mongolia, China
  • Received:2016-11-16 Revised:2017-02-18 Online:2017-10-05 Published:2017-10-05

基于CO2捕集的煤基费托合成油-动力多联产系统(火用)分析

于戈文, 王延铭, 杨小丽, 吴刚强   

  1. 内蒙古科技大学化学与化工学院, 内蒙古 包头 014010
  • 通讯作者: 于戈文(1971-),男,博士,教授,研究方向为煤化工、化工系统工程.
  • 作者简介:于戈文(1971-),男,博士,教授,研究方向为煤化工、化工系统工程.E-mail:404122693@qq.com.
  • 基金资助:
    国家自然科学研究基金(21466029)及内蒙古自然科学研究基金(2014MS0210)项目。

Abstract: For researching the performance of polygeneration systems in energy saving and emission reduction,three different polygeneration systems were designed and modeled by Aspen software. Based on the exergy theory,the total exergy efficiency and the exergy losses of sub-systems were simulated. Carbon capture ratio and carbon emission ratio were also analyzed. When the syngas split ratio of the chemical engineering side was 25%(Case-1),75%(Case-2) and 100%(Case-3),the FT Syncrude exergy was 1039.02MW,2928.91MW and 3905.22MW,and the electricity exergy was 2596.1MW,1235.4MW and 476.4MW with the total exergy efficiency of 42.80%,49.87% and 52.46%,respectively. The exergy losses were mainly distributed in the process getting along with the chemical exergy transformation such as the gasification,the FT synthesis and the separation processes. With increasing syngas split ratio in the chemical engineering side,the carbon dioxide capture ratio decreaseed from 79.36% to 52.98%. And the proportion of the carbon emission to the total carbon input fell from 5.32% to 3.01%. The results showed that the total exergy efficiency rose with increasing chemical exergy conversion degree. The chemical engineering side had a greater impact on exergy efficiency than power side. The tandem type polygeneration systems had more efficient and reasonable energy utilization than the polygeneration systems in parallel. The carbon emission reduced with increasing the syngas amount in the chemical engineering side.

Key words: simulation, exergy, syngas, synthesis

摘要: 为了研究多联产在节能和减排方面的表现,应用Aspen模拟软件设计并模拟了3个不同工艺路线多联产系统。运用有效能理论计算并分析了各多联产系统总(火用)效率及各子系统(火用)损失,同时计算了碳捕集率和排放率。得出当化工端合成气分流比分别为25%(案例-1)、75%(案例-2)、100%(案例-3)时,费托(FT)合成油的(火用)值分别为1039.02MW、2928.91MW以及3905.22MW,发电的(火用)值分别为2596.1MW、1235.4MW以及476.4MW,系统总(火用)效率分别为42.80%、49.87%以及52.46%。多联产系统的(火用)损失主要分布在伴随着化学(火用)转化的气化过程、FT合成过程和分离过程。随着化工端合成气分流比的增加,二氧化碳的捕集率从79.36%减少到52.98%,而排放的碳单质也从占输入系统总碳量的5.32%下降到3.01%。结果表明:系统总(火用)效率随着合成气的化学(火用)转化程度增大而增大,化工端比动力端对系统(火用)效率有更大影响;串联型多联产与并联型多联产相比能够更加高效、合理地利用能量;随着合成气用于化工端的比例增加,碳排放随之减少。

关键词: 模拟, (火用), 合成气, 合成

CLC Number: 

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