Process modelling, validation and analysis of rotating packed bed stripper in the context of intensified CO2 capture with MEA

Tohid N. Borhani; Eni Oko; Meihong Wang

Journal of Industrial and Engineering Chemistry, Vol.75, 285-295, July, 2019

DOI10.1016/j.jiec.2019.03.040 Export Citation

Process modelling, validation and analysis of rotating packed bed stripper in the context of intensified CO2 capture with MEA

Tohid N. Borhani, Eni Oko, and Meihong Wang^†

Department of Chemical and Biological Engineering, The University of Sheffield, Sheffield S1 3JD, UK

E-mail:

Rotating packed bed (RPB) system has applications in CO2 removal using chemical solvents which can reduce the size about ten times compared to common packed bed (PB) system. In this study, RPB stripper using monoethanolamine (MEA) solution is modelled in gPROMS® software. The model has been validated using experimental data from literature and show good agreement. In addition to stripper modelling and validation, the process analysis is accomplished in this study by assessing the influence of four parameters namely rotor speed, reboiler temperature, flow rate of rich liquid, and pressure on desorption efficiency and desorption energy.

Keywords:Carbon capture;Process intensification;Rotating packed bed;Stripper;Monoethanolamine;Process analysis

[References]

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Cheng HH, Lai CC, Tan CS, Int J Greenhouse Gas Control, 16, 206
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[1] Zhang Z, Borhani TNG, El-Naas MH, Academic Press, pp.997 2018.

[2] Borhani TNG, Azarpour A, Akbari V, Wan Alwi SR, Manan ZA, Int J Greenhouse Gas Control, 41, 142 (2015)

[3] Tobiesen FA, Svendsen HF, Ind. Eng. Chem. Res., 45(8), 2489 (2006)

[4] Frimpong RA, Remias JE, Neathery JK, Liu K, Int J Greenhouse Gas Control, 9, 124 (2012)

[5] Cheng HH, Lai CC, Tan CS, Int J Greenhouse Gas Control, 16, 206

[6] Simioni M, Kentish SE, Stevens GW, J. Membr. Sci., 378(1-2), 18 (2011)

[7] Oyenekan BA, Rochelle GT, AIChE J., 53(12), 3144 (2007)

[8] Sakwattanapong R, Aroonwilas A, Veawab A, Ind. Eng. Chem. Res., 44(12), 4465 (2005)

[9] Oyenekan BA, PhD Thesis, The University of Texas at Austin, (2007).

[10] Harun N, PhD Thesis, University of Waterloo (2012).

[11] Oexmann J, Kather A, Int J Greenhouse Gas Control, 4, 36 (2010)

[12] Galindo P, Schaffer A, Brechtel K, Unterberger S, Scheffknecht G, Fuel, 101, 2 (2012)

[13] Li X, Wang S, Chen C, Energy Procedia, 37, 1836 (2013)

[14] Oyenekan BA, Rochelle GT, Int J Greenhouse Gas Control, 3, 121 (2009)

[15] Mores P, Scenna N, Mussati S, Energy, 45, 1042 (2012)

[16] Weiland RH, Rawal M, Rice RG, AIChE J., 28, 963 (1982)

[17] Khalilpour R, Abbas A, Sep. Purif. Technol., 132, 149 (2014)

[18] Li T, Keener TC, Int J Greenhouse Gas Control, 51, 290 (2016)

[19] Rezazadeh F, Gale WF, Lin YJ, Rochelle GT, Ind. Eng. Chem. Res., 55(16), 4622 (2016)

[20] Wang M, Joel AS, Ramshaw C, Eimer D, Musa NM, Appl. Energy, 158, 275 (2015)

[21] Neumann K, Gladyszewski K, Gross K, Qammar H, Wenzel D, Gorak A, Skiborowski M, Chem. Eng. Res. Des., 134, 443 (2018)

[22] Karmakar S, Bhowal A, Das P, Chem Eng Process Process Intensif, 132, 187 (2018)

[23] Borhani TN, Oko E, Wang M, J. Clean Prod., 204, 1124 (2018)

[24] Oko E, Ramshaw C, Wang M, Appl Energy, 223, 302 (2018)

[25] Joel AS, PhD Thesis, University of Hull, (2016).

[26] Joel AS, Wang MH, Ramshaw C, Oko E, Appl. Energy, 203, 11 (2017)

[27] Jassim MS, Rochelle G, Eimer D, Ramshaw C, Ind. Eng. Chem. Res., 46(9), 2823 (2007)

[28] Pantelides CC, Nauta M, Matzopoulos M, Equation-Oriented Process Modelling Technology: Recent Advances & Current Perspectives, (2015).

[29] Smith JM, Van Ness HC, Abbott MM, Introduction to chemical engineering thermodynamics, McGraw-Hill, 2005.

[30] Kvamsdal HM, Jakobsen JP, Hoff KA, Chem Eng Process Process Intensif, 48, 135 (2009)

[31] Harun N, Nittaya T, Douglas PL, Croiset E, Ricardez-Sandoval LA, Int J Greenhouse Gas Control, 10, 295 (2012)

[32] Austgen DM, Rochelle GT, Peng X, Chen CC, Ind. Eng. Chem. Res., 28, 1060 (1989)

[33] Luo X, Hartono A, Hussain S, Svendsen HF, Chem. Eng. Sci., 123, 57 (2015)

[34] Astarita G, Savage DW, Chem. Eng. Sci., 35, 1755 (1980)

[35] Tobiesen FA, Svendsen HF, Hoff KA, Int J Green Energy, 2, 201 (2005)

[36] Edwards TJ, Maurer G, Newman J, Prausnitz JM, AIChE J., 24, 966 (1978)

[37] Kent RL, Eisenberg B, Hydrocarb. Process., 55, 87 (1976)

[38] Aronu UE, Gondal S, Hessen ET, Haug-Warberg T, Hartono A, Hoff KA, Svendsen HF, Chem. Eng. Sci., 66, 6393 (2011)

[39] Weiland RH, Dingman JC, Cronin DB, Browning GJ, J. Chem. Eng. Data, 43(3), 378 (1998)

[40] Hsu CH, Li MH, J. Chem. Eng. Data, 42(3), 502 (1997)

[41] Agbonghae EO, Hughes KJ, Ingham DB, Ma L, Pourkashanian M, Ind. Eng. Chem. Res., 53(19), 8291 (2014)

[42] Onda K, Takeuchi H, Okumoto Y, J. Chem. Eng. Jpn., 1, 56 (1968)

[43] Tung HH, Mah RSH, Chem. Eng. Commun., 39, 147 (1985)

[44] Ying JR, Eimer DA, Yi WJ, Ind. Eng. Chem. Res., 51(19), 6958 (2012)

[45] Fairbanks DF, Wilke CR, Ind. Eng. Chem., 42, 471 (1950)

[46] Llerena-Chavez H, Larachi F, Chem. Eng. Sci., 64(9), 2113 (2009)

[47] Burns JR, Jamil JN, Ramshaw C, Chem. Eng. Sci., 55(13), 2401 (2000)

[48] Chilton TH, Colburn AP, Ind Eng Chem, 26, 1183 (1934)

[49] Prausnitz JM, Lichtenthaler RN, de Azevedo EG, Molecular Thermodynamics of Fluid-Phase Equilibria, Pearson Education, 1998.

[50] Borhani TNG, Bagheri M, Manan ZA, Fluid Phase Equilib., 360, 423 (2013)

[51] Borhani TNG, Saniedanesh M, Bagheri M, Lim JS, Water Res., 98, 344 (2016)

[52] Singh SP, Wilson JH, Counce RM, Lucero AJ, Reed GD, Ashworth RA, Elliott MG, Ind. Eng. Chem. Res., 31, 574 (1992)