Numerical study on absorption of carbon dioxide and mass transfer performance in hollow fiber membrane contactor

doi:10.3969/j.issn.0438-1157.2014.06.045

Abstract

Abstract: A type of process, which absorbs carbon dioxide (CO₂) from flue gas in hollow fiber membrane contactor, has been considered as one of clean, high efficient and the most promising decarburization technologies. A two-dimensional mathematical model was developed for absorption of CO₂ from parallel countercurrent mixed gas by hollow fiber membrane contactor. By using finite element method, CO₂ removal(decarburization) and mass transfer performance of three absorbents EEA(ethyl-ethanolamine), EDA(ethylenediamine) and PZ(piperazine) were simulated at various operation conditions in which axial and radial diffusion in membrane contactor as well as diffusion in fiber and membrane pores and non-wetting condition were considered. The simulation results show that the order of decarburization performance is PZ > EDA > EEA. The influence of the gas phase parameters on CO₂ removal and mass transfer is more significant than that of liquid phase parameters. With increase of gas flow rate, CO₂ concentration, and gas temperature, the decarburization efficiency decreases. While the CO₂ removal efficiency goes up when liquid flow rate, solvent concentration, and liquid temperature increase. However, the CO₂ mass transfer rate speeds up with increase of all parameters except gas temperature. So, the suitable control of liquid parameters is required, which are not over high to prevent adverse effects on CO₂ absorption.

Key words: hollow fiber membrane contactor, carbon dioxide, operating parameters, model, numerical simulation

摘要： 中空纤维膜吸收烟气中CO₂是一种清洁、高效、最具潜力的脱碳技术方法之一。本文建立了一个二维的中空纤维膜接触器平行逆流吸收混合气中CO₂的非润湿模型。考虑轴向和径向扩散，模拟了EEA、EDA和PZ 3种吸收剂在不同操作条件下对CO₂的脱除效果和传质性能。结果表明：脱碳性能从大到小为PZ>EDA>EEA；气相参数对脱碳和传质的影响比液相参数更显著；提高气体流速、CO₂浓度和气温，脱碳率均会下降；提高液速、吸收剂浓度和液温，脱碳率均增大，而传质速率只有在提高气温时会下降，其他参数的升高均会使其增大；应采用适当的液相参数，防止操作参数过高带来的不利影响。

关键词: 中空纤维膜接触器, 二氧化碳, 操作参数, 模型, 数值模拟

CLC Number:

TQ028.8

ZHANG Li, JU Shunxiang, YAN Yunfei, ZHANG Zhi'en. Numerical study on absorption of carbon dioxide and mass transfer performance in hollow fiber membrane contactor[J]. CIESC Journal, 2014, 65(6): 2285-2293.

张力, 鞠顺祥, 闫云飞, 张智恩. 中空纤维膜接触器脱碳和传质性能的数值研究[J]. 化工学报, 2014, 65(6): 2285-2293.

References 22

[1]	Wang Qiuhua(王秋华), Zhang Weifeng(张卫风), Fang Mengxiang(方梦祥), Luo Zhongyang(骆仲泱),Cen Kefa(岑可法). Separation of CO2 in flue gas by membrane absorption in China [J]. Environmental Science & Technology(环境科学与技术),2009, 32(7):68-74
[2]	Rao A B, Rubin E S . A technical, economic, and environmental assessment of amine-based CO2 capture technology for power plant greenhouse gas control [J]. Environ. Sci. Technol., 2002, 36: 4467-4475
[3]	Ma Jun(马骏). Study on the separation of carbon dioxide from the mixed gas through membrane contactor [D]. Nanjing: Nanjing University of Science and Technology, 2004
[4]	Klaassen R, Feron P H M, Jansen A E. Membrane contactors in industrial applications [J]. Chemical Engineering Research and Design, 2005, 83(3):234-246
[5]	Al-Marzouqi Mohamed H, El-Naas Muftah H. Modeling of CO2 absorption in membrane contactors [J]. Separation and Purification Technology, 2008, 59: 286-293
[6]	Lü Yuexia(吕月霞), Yu Xinhai (于新海), Tu Shandong(涂善东). Experiment of CO2 separation from flue gases by membrane gas absorption [J]. Journal of Nanjing University of Technology: Natural Science Edition(南京工业大学学报:自然科学版), 2009, 31(5): 96-101
[7]	Faiz Rami, Al-Marzouqi M. Mathematical modeling for the simultaneous absorption of CO2 and H2S using MEA in hollow fiber membrane contactors [J]. Journal of Membrane Science, 2009, 342(1/2):269-278
[8]	Chen Wei(陈炜), Zhu Baoku(朱宝库), Wang Jianli(王建黎), Xu Youyi(徐又一), Xu Zhikang(徐志康). Study on hollow fiber membrane contactor for the separation of carbon dioxide from carbon dioxide-nitrogen mixture [J]. Membrane Science and Technology(膜科学与技术), 2004, 24(1) :32-37
[9]	Wang R, Li D F, Liang D T. Modeling of CO2 capture by three typical amine solutions in hollow fiber membrane contactors [J]. Chemical Engineering and Processing, 2004, 43: 849-856
[10]	Happel J. Viscous flow relative to arrays of cylinders [J]. AIChE J., 1959, 5:174-177
[11]	Yan Shuiping, Fang Mengxiang, Zhang Weifeng, Wang Shuyuan, Xu Zhikang, Luo Zhongyang, Cen Kefa. Experimental study on the separation of CO2 from flue gas using hollow fiber membrane contactors without wetting [J]. Fuel Process Technology, 2007, 88:501-511
[12]	Paul S, Ghoshal A K, Mandal B. Theoretical studies on separation of CO2 by single and blended aqueous alkanolamine solvents in flat sheet membrane contactor (FSMC) [J]. Chem. Eng. J., 2008, 144:352-360
[13]	Li Juelin, Henni Amr, Tontiwachwuthikul Paitoon. Reaction kinetics of CO2 in aqueous ethylenediamine, ethyl ethanolamine, and diethyl monoethanolamine solutions in the temperature range of 298-313 K, using the stopped-flow technique [J]. Ind. Eng. Chem. Res., 2007, 46: 4426-4434
[14]	Bishnoi Sanjay, Rochelle Gary T. Absorption of carbon dioxide into aqueous piperazine:reaction kinetics, mass transfer and solubility [J]. Chemical Engineering Science, 2000, 55: 5531-5543
[15]	Sun Wei-Chen, Yong Chia-Bao, Li Meng-Hui. Kinetics of the absorption of carbon dioxide into mixed aqueous solutions of 2-amino-2-methyl-l-propanol and piperazine [J]. Chemical Engineering Science, 2005,60: 503-516
[16]	Eslami S, Mousavi S M, Danesh S, Banazadeh H. Modeling and simulation of CO2 removal from power plant flue gas by PG solution in a hollow fiber membrane contactor [J]. Advances in Engineering Software, 2011, 42: 612-620
[17]	Sohrabi Mahmoud Reza, Marjani Azam, Moradi Sadegh, Davallo Mehran, Shirazian Saeed. Mathematical modeling and numerical simulation of CO2 transport through hollow-fiber membranes [J]. Applied Mathematical Modelling, 2011, 35: 174-188
[18]	Zhang Hong Yan, Wang Rong, Liang David Tee, Tay Joo Hwa. Theoretical and experimental studies of membrane wetting in the membrane gas-liquid contacting process for CO2 absorption [J]. Journal of Membrane Science, 2008, 308:162-170
[19]	Kim Young-Seok, Yang Seung-Man. Absorption of carbon dioxide through hollow fiber membranes using various aqueous absorbents [J]. Separation and Purification Technology, 2000, 21: 101-109
[20]	deMontigny David, Tontiwachwuthikul Paitoon, Chakmab Amit. Using polypropylene and polytetrafluoroethylene membranes in a membrane contactor for CO2 absorption [J]. Journal of Membrane Science, 2006, 277: 99-107
[21]	Razavi Seyed Mohammad Reza, Razavi Seyed Mohammad Javad, Miri Taghi, Shirazian Saeed. CFD simulation of CO2 capture from gas mixtures in nanoporous membranes by solution of 2-amino-2-methyl-1-propanol and piperazine [J]. International Journal of Greenhouse Gas Control, 2013, 15: 142-149
[22]	Shirazian Saeed, Moghadassi Abdolreza, Moradi Sadegh. Numerical simulation of mass transfer in gas-liquid hollow fiber membrane contactors for laminar flow conditions [J]. Simulation Modeling Practice and Theory, 2009, 17:708-718