Characterizing the catalyst fluidization with field synergy to improve the amine absorption for CO2 capture

doi:10.1016/j.cjche.2018.11.003

摘要/Abstract

摘要： There are great interests to capture the CO₂ to control the greenhouse gas emission. Amine absorption of CO₂ is being taken as an effective way to capture CO₂ in industry. However, the amine absorption of CO₂ is cost-ineffective due to great energy consumption and solution consumption. In order to reduce the capture cost, catalyst fluidization is proposed here to intensify the mass transfer and heat transfer. Catalyst fluidization with field synergy and DFT model is developed by incorporating the effects of catalyst reaction kinetics, drag force and multi-field into the mass transfer, heat transfer, fluid flow and catalyst collision. Experiments with an improved distributor are performed well to validate the model. The reaction kinetics is determined by the DFT simulation and experiment. The mass transfer coefficient in the fluidized reactor is identified as 17% higher than the conventional packed reactor. With the field synergy of catalyst fluidization, the energy consumption for CO₂ desorption is reduced by 9%. Stepwise operation and inclination reactor are used to improve catalyst fluidization process.

关键词: CO₂ capture, Catalyst fluidization, Mass transfer, DFT, Energy consumption, Field synergy

Abstract: There are great interests to capture the CO₂ to control the greenhouse gas emission. Amine absorption of CO₂ is being taken as an effective way to capture CO₂ in industry. However, the amine absorption of CO₂ is cost-ineffective due to great energy consumption and solution consumption. In order to reduce the capture cost, catalyst fluidization is proposed here to intensify the mass transfer and heat transfer. Catalyst fluidization with field synergy and DFT model is developed by incorporating the effects of catalyst reaction kinetics, drag force and multi-field into the mass transfer, heat transfer, fluid flow and catalyst collision. Experiments with an improved distributor are performed well to validate the model. The reaction kinetics is determined by the DFT simulation and experiment. The mass transfer coefficient in the fluidized reactor is identified as 17% higher than the conventional packed reactor. With the field synergy of catalyst fluidization, the energy consumption for CO₂ desorption is reduced by 9%. Stepwise operation and inclination reactor are used to improve catalyst fluidization process.

Key words: CO₂ capture, Catalyst fluidization, Mass transfer, DFT, Energy consumption, Field synergy

Yunsong Yu, Chen Zhang, Zaoxiao Zhang, Geoff Wang. Characterizing the catalyst fluidization with field synergy to improve the amine absorption for CO₂ capture[J]. 中国化学工程学报, 2019, 27(7): 1608-1617.

Yunsong Yu, Chen Zhang, Zaoxiao Zhang, Geoff Wang. Characterizing the catalyst fluidization with field synergy to improve the amine absorption for CO₂ capture[J]. Chinese Journal of Chemical Engineering, 2019, 27(7): 1608-1617.

参考文献

[1] E. Karlsson, M. Gourdon, L. Vamling, Solid dissolution into a vertical falling film under industrial-like conditions, Ind. Eng. Chem. Res. 53(22) (2014) 9478-9787.
[2] P.J. Cheng, K.C. Liu, C.C. Wang, Nonlinear evolution of the travelling waves in roll coating flows of thin viscoelastic polymer falling films, Appl. Mech. Mater. 479-480(2016) 45-49.
[3] S.I. Cheong, K.Y. Choi, A study on the polymer layer-forming phenomena in a rotating disk polycondensation reactor, J. Appl. Polym. Sci. 55(13) (2010) 1819-1826.
[4] Z. Xi, L. Zhao, Z. Liu, New falling film reactor for melt polycondensation process, Macromol. Symp. 259(1) (2007) 10-16.
[5] Z. Liu, J. Shi, Grid falling film devolatilizer, 2011, U.S. Pat., 7959133.
[6] G.H. Hu, I. Kadri, C. Picot, One-line measurement of the residence time distribution in screw extruders, Polym. Eng. Sci. 39(5) (1999) 930-939.
[7] K. Yang, C. Xin, D. Yu, B. Yan, J. Pang, Y. He, Numerical simulation and experimental study of pressure and residence time distribution of triple-screw extruder, Polym. Eng. Sci. 55(1) (2015) 156-162.
[8] S. Mohammadi, K.V.K. Boodhoo, Online conductivity measurement of residence time distribution of thin film flow in the spinning disc reactor, Chem. Eng. J. 207-208(2012) 885-894.
[9] F. Visscher, J.D. Hullu, M.H.J.M.D. Croon, J.V.D. Schaaf, J.C. Schouten, Residence time distribution in a single-phase rotor-stator spinning disk reactor, AIChE J. 59(7) (2013) 2686-2693.
[10] X. Feng, D.A. Patterson, M. Balaban, E.A.C. Emanuelsson, Characterization of liquid flow in the spinning cloth disc reactor:Residence time distribution, visual study and modeling, Chem. Eng. J. 235(2014) 356-367.
[11] J.T. Adeosun, A. Lawal, Numerical and experimental studies of mixing characteristics in a T-junction microchannel using residence-time distribution, Chem. Eng. Sci. 64(10) (2009) 2422-2432.
[12] L. Zhang, Q. Pan, G.L. Rempel, Residence time distribution in a multistage agitated contactor with Newtonian fluids:CFD prediction and experimental validation, Ind. Eng. Chem. Res. 46(11) (2007) 3538-3546.
[13] Y. Gao, B.J. Glasser, M.G. Ierapetritou, A. Cuitino, F.J. Muzzio, J.W. Beeckman, N. A. Fassbender, W.G. Borghard, Measurement of residence time distribution in a rotary calciner, AIChE J. 59(59) (2013) 4068-4076.
[14] X. Zhang, Z. Xu, L. Feng, X. Song, G. Hu, Assessing local residence time distributions in screw extruders through a new in-line measurement instrument, Polym. Eng. Sci. 46(4) (2006) 510-519.
[15] X. Zhang, L. Feng, S. Hoppe, G. Hu, Residence revolution, and residence volume distributions in twin-screw extruders, Polym. Eng. Sci. 48(1) (2008) 19-28.
[16] H. Fang, F. Mighri, A. Ajji, P. Cassagnau, S. Elkoun, Flow behavior in a corotating twin-screw extruder of pure polymers and blends:Characterization by fluorescence monitoring technique, J. Appl. Polym. Sci. 120(4) (2011) 2304-2312.
[17] S. Laske, A. Witschnigg, R.K. Selvasankar, C. Holzer, Measuring the residence time distribution in a twin screw extruder with the use of NIR-spectroscopy, J. Appl. Polym. Sci. 131(6) (2014) 596-602.
[18] S. Kalliadasis, C. Ruyer-Quil, B. Scheid, M.G. Velarde, Falling liquid films, Springer, London, 2011.
[19] G. Tryggvason, B. Bunner, A. Esmaeeli, D. Juric, N. Al-Rawahi, W. Tauber, J. Han, S. Nas, Y.J. Jan, A front-tracking method for the computations of multiphase flow, J. Comput. Phys. 169(2) (2001) 708-759.
[20] K. Moran, J. Inumaru, M. Kawaji, Instantaneous hydrodynamics of a laminar wavy liquid film, Int. J. Multiphase Flow 28(5) (2002) 731-755.
[21] D. Gao, N.B. Morley, V. Dhir, Numerical simulation of wavy falling film flow using VOF method, J. Comput. Phys. 192(2) (2003) 624-642.
[22] F. Losasso, R. Fedkiw, S. Osher, Spatially adaptive techniques for level set methods and incompressible flow, Comput. Fluids 35(10) (2006) 995-1010.
[23] W. Bo, X. Liu, J. Glimm, X. Li, A robust front tracking method:Verification and application to simulation of the primary breakup of a liquid jet, SIAM J. Sci. Comput. 33(4) (2011) 1505-1524.
[24] G. Tryggvason, M. Ma, J. Lu, DNS-assisted modeling of bubbly flows in vertical channels, Nucl. Sci. Eng. 184(2016) 312-320.
[25] M. Ma, J. Lu, G. Tryggvason, Using statistical learning to close two-fluid multiphase flow equations for a simple bubbly system, Phys. Fluids 27(2015) 092101.
[26] M. Ma, J. Lu, G. Tryggvason, Using statistical learning to close two-fluid multiphase flow equations for bubbly flows in vertical channels, Int. J. Multiphase Flow 85(2016) 336-347.
[27] T. Nosoko, P.N. Yoshimura, T. Nagata, K. Oyakawa, Characteristics of twodimensional waves on a falling liquid film, Chem. Eng. Sci. 51(5) (1996) 725-732.
[28] E.W. Llewellin, E.D. Bello, J. Taddeucci, P. Scarlato, S.J. Lane, The thickness of the falling film of liquid around a Taylor bubble, Proc. R. Soc. A Math. Phys. Eng. Sci. 468(2140) (2011) 1041-1064.
[29] F.K. Wasden, A.E. Dukler, Insights into the hydrodynamics of free falling wavy films, AIChE J. 35(2) (1989) 187-195.
[30] W. Ambrosini, N. Forgione, F. Oriolo, Statistical characteristics of a water film falling down a flat plate at different inclinations and temperatures, Int. J. Multiphase Flow 28(9) (2002) 1521-1540.
[31] X. Chen, S. Shen, Y. Wang, J. Chen, J. Zhang, Measurement on falling film thickness distribution around horizontal tube with laser-induced fluorescence technology, Int. J. Heat Mass Transf. 89(2015) 707-713.
[32] P.V. Danckwerts, Continuous flow systems:Distribution of residence times, Chem. Eng. Sci. 2(1953) 1-13.
[33] J.H. Ham, B. Platzer, Semi-empirical equations for the residence time distributions in disperse systems-Part 1:Continuous phase, Chem. Eng. Technol. 27(2004) 1172-1178.
[34] S. Chen, J. Ma, X. Zhang, W. Chen, Numerical simulation of the behavior of high-viscosity fluids falling film flow down the vertical wavy wall, Asia Pac. J. Chem. Eng. 12(1) (2017) 97-109.
[35] J.U. Brackbill, D.B. Kothe, C. Zemach, A continuum method for modeling surface tension, J. Comput. Phys. 100(2) (1992) 335-354.
[36] L. Zhao, R.L. Cerro, Experimental characterization of viscous films flows over complex surfaces, Int. J. Multiphase Flow 18(4) (1992) 495-516.
[37] L. Chen, G. Hu, Applications of a statistical theory in residence time distributions, AICHE J. 39(9) (1993) 1558-1562.
[38] A.A. Mouza, M.N. Pantzali, S.V. Paras, Falling film and flooding phenomena in small diameter vertical tubes:The influence of liquid properties, Chem. Eng. Sci. 60(18) (2005) 4981-4991.
[39] C.E. Meza, V. Balakotaiah, Modeling and experimental studies of large amplitude waves on vertically falling films, Chem. Eng. Sci. 63(19) (2008) 4704-4734.
[40] S. Bo, X. Ma, Z. Lan, H. Chen, J. Chen, Numerical simulation on wave behavior and flow dynamics of laminar-wavy falling films:Effect of surface tension and viscosity, Can. J. Chem. Eng. 90(1) (2012) 61-68.
[41] P. Valluri, O.K. Matar, G.F. Hewitt, M.A. Mendes, Thin film flow over structured packings at moderate Reynolds numbers, Chem. Eng. Sci. 60(7) (2005) 1965-1975.

Characterizing the catalyst fluidization with field synergy to improve the amine absorption for CO₂ capture

Characterizing the catalyst fluidization with field synergy to improve the amine absorption for CO₂ capture

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