Modification of process and optimization for CO2 capture systems using amine solution

doi:10.3969/j.issn.0438-1157.2013.10.036

Abstract

Abstract: Capturing CO₂ from coal-fired power plants using monoethanolamine(MEA)solution is a relatively mature and feasible technology at present.However,high energy requirement is its main drawback.The energy requirement can be reduced by modification of process and optimization.A rate-based model in Aspen Plus simulator is used to simulate the conventional flow path and its modification.The process modifications include absorber intercooling,rich split,lean vapor compression,split flow and the combination of rich split and lean vapor compression.The results show that combination of rich split and lean vapor compression as well as the rich split are the first and the second best process improvement,save of regeneration energy and decrease of equivalent work are 28.2% and 19.3% as well as 11.9% and 11.8%,respectively.For lean vapor compression,save of regeneration energy can be up to 14.1%,while the decrease of equivalent work is only 4.1%.The absorber intercooling and split flow is relatively limited for energy saving.

Key words: monoethanolamine, CO₂ capture, flow sheet, regeneration energy

摘要： 采用一乙醇胺(MEA)进行燃煤电厂烟气脱碳是目前比较成熟和可行的技术,但是存在再生能耗高的严重缺陷。胺法脱碳系统流程改进及优化能有效降低再生能耗。应用Aspen Plus软件基于速率模型对传统胺法脱碳流程及其改进流程进行模拟研究。这些改进的流程包括吸收塔中间冷却流程、富液分流流程、贫液蒸汽再压缩流程、分流流程及富液分流与贫液蒸汽再压缩整合流程。研究结果表明:富液分流与贫液蒸汽再压缩整合流程节能效果最好,和传统流程相比再生能耗及等量功分别下降28.2%和11.9%。节能效果其次的是富液分流流程,再生能耗和等量功分别下降19.3%和11.8%。贫液蒸汽再压缩流程使再生能耗下降了14.1%,而等量功只下降了4.1%。吸收塔中间冷却流程和分流流程节能效果比较有限。

关键词: 一乙醇胺, 脱碳, 流程, 再生能耗

CLC Number:

TK09

LI Xiaofei, WANG Shujuan, CHEN Changhe. Modification of process and optimization for CO₂ capture systems using amine solution[J]. CIESC Journal, 2013, 64(10): 3750-3759.

李小飞, 王淑娟, 陈昌和. 胺法脱碳系统流程改进及优化模拟[J]. 化工学报, 2013, 64(10): 3750-3759.

References 27

[1]	IPCC.Special Report on Carbon Dioxide Capture and Storage[M].Cambridge,UK:Cambridge University Press,2005
[2]	Bai Bing(白冰),Li Xiaochun(李小春),Liu Yanfeng(刘延锋),Zhang Yong(张勇).Preliminary study on CO2 industrial point sources and their distribution in China[J].Chinese Journal of Rock Mechanics and Engineering(岩石力学与工程学报),2006,25:2918-2923
[3]	MacDowell N,Florin N,Buchard A,et al.An overview of CO2 capture technologies[J].Energy ＆ Environmental Science,2010,3:1645-1669
[4]	Rochelle G.Amine scrubbing for CO2 capture[J].Science,2009,325:1652-1654
[5]	Damen K,Troost M,Faaij A,Turkenbury W.A comparison of electricity and hydrogen production systems with CO2 capture and storage(Part A):Review and selection of promising conversion and capture technologies[J].Progress in Energy and Combustion Science,2006,32:215-246
[6]	Wang Zhaoliang(王照亮),Wang Chengyun(王成运),Li Qingfang(李清方),Zhang Jian(张建).Pinch analysis of CO2 capture in power plant and process integration energy saving[J].CIESC Journal(化工学报),2012,63(2):593-598
[7]	Sakwattanapong R,Aroonwilas A,Veawab A.Behavior of reboiler heat duty for CO2 capture plants using regenerable single and blended alkanolamine[J].Ind. Eng. Chem.Res.,2005,44:4465-4473
[8]	Du Min(杜敏),Zhang Li(张力),Feng Bo(冯波).Effect of adipic acid on absorption and desorption of CO2 with MEA solution[J].CIESC Journal(化工学报),2011,62(2):412-418
[9]	Chen Yanjie(陈晏杰),Yao Yuehua(姚月华),Jiang Zhenxi(江振西),Zhang Xiangping(张香平),Ren Baozeng(任保增),Dong Haifeng(董海峰),Huang Ying(黄莺),Zhang Suojiang(张锁江).Process analysis of CO2 capture from flue gas with MEA-AMP mixed amines[J].Computers and Applied Chemistry(计算机与应用化学),2012,29(1):113-116
[10]	Lu B,Jin J,Zhang L,Li W.Absorption of carbon dioxide into aqueous blend of monoethanolamine and 1-buty1-3-methylimidazolium tetrafluoroborate[J].International Journal of Greenhouse Gas Control,2012,11:152-157
[11]	Rodriguez N,Mussati S,Scenna N.Optimization of post-combustion CO2 process using DEA-MDEA mixtures[J].Chemical Engineering Research and Design,2011,89:1763-1773
[12]	Sanchez L,Meindersma G,Haan A.Solvent properties of functionalized ionic liquids for CO2 absorption[J].Chemical Engineering Research and Design,2007,85:31-39
[13]	Aleixo M,Prigent M,Gibert A.Physical and chemical properties of DMXTM solvents//10th International Conference on Greenhouse Gas Control Technologies[C].Amsterdam:Energy Procedia,2011:148-155
[14]	Zhang J,Nwani O,Tan Y.Carbon dioxide absorption into biphasic amine solvent with solvent loss reduction[J].Chemical Engineering Research and Design,2011,89:1190-1196
[15]	Wang Mingxi(汪明喜),Fang Mengxiang(方梦祥),Wang Zhen(汪桢),Pan Yili(潘一力),Luo Zhongyang(骆仲泱).CO2 absorption and desorption by phase transition lipophilic amine solvents[J].Journal of Zhejiang University(浙江大学学报),2013,47:1-7
[16]	Oyenekan B,Rochelle G.Alternative stripper configurations for CO2 capture by aqueous amines[J].AIChE J.,2007,53(12):3144-3154
[17]	Schach M,Schneider R,Schramm H,Repke J.Techno-economic analysis of postcombustion processes for the capture of carbon dioxide from power plant fuel gas[J].Ind.Eng.Chem.Res.,2010,49:2363-2370
[18]	Karimi M,Hillestad M,Svendsen H.Capital costs and energy considerations of different alternative stripper configurations for post combustion CO2 capture[J].Chemical Engineering Research and Design,2011,89:1229-1236
[19]	Wagener D,Rochelle G.Stripper configurations for CO2 capture by aqueous monoethanolamine[J].Chemical Engineering Research and Design,2011,89:1639-1646
[20]	Moullec Y,Kanniche M.Screening of flowsheet modifications for an efficient monoethanolamine(MEA)based post-combustion CO2 capture[J].International Journal of Greenhouse Gas Control,2011,5:727-740
[21]	Amrollahi Z,Ystad P,Ertesvag I,Bolland O.Optimized process configurations of post-combustion CO2 capture for natural-gas-fired power plant-power plant efficiency analysis[J].International Journal of Greenhouse Gas Control,2012,8:1-11
[22]	Plaza J,Chen E,Rochelle G.Absorber intercooling in CO2 absorption by piperazine-promoted potassium carbonate[J].AIChE J.,2010,56(4):905-914
[23]	Aroowilas A,Veawab A.Integration of CO2 capture unit using single and blended-amines into supercritical coal-fired power plants:implications for emission and energy management[J].International Journal of Greenhouse Gas Control,2007,1:143-150
[24]	Cousins A,Wardhaugh L,Feron P.A survey of process flow sheet modifications for energy efficient CO2 capture from flue gases using chemical absorption[J].International Journal of Greenhouse Gas Control,2011,5:605-619
[25]	Chang H,Shih C.Simulation and optimization for power plant flue gas CO2 absorption-stripping systems[J].Separation Science and Technology,2005,40:877-909
[26]	Liu Liaobo(刘练波),Huang Bin(黄斌),Gao Shiwang(郜时旺),Xu Shisen(许世森).A pilot plant process and key equipment for capture CO2 3000-5000 t/a in coal-fired power station[J].Electrical Equipment(电力设备),2008,9(5):21-24
[27]	Abu-Zahra M,Schneiders L,Nieder J,Feron P,Versteeg G.CO2 capture from power plants(Part 1):A parametric study of the technical performance based on monoethanolamine[J].International Journal of Greenhouse Gas Control,2007,1:37-46

Modification of process and optimization for CO₂ capture systems using amine solution

胺法脱碳系统流程改进及优化模拟

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