Compressibility induced bubble size variation in bubble column reactors: Simulations by the CFD-PBE

doi:10.1016/j.cjche.2018.04.032

Abstract

Abstract: Bubble column reactors can be simulated by the two fluid model (TFM) coupled with the population balance equation (PBE). For the large industrial bubble columns, the compressibility due to the pressure difference may introduce notable bubble size variation. In order to address the compressibility effect, the PBE should be reformulated and coupled with the compressible TFM. In this work, the PBE with a compressibility term was formulated from single bubble dynamics, the mean Sauter diameters predicted by the compressible TFM coupled with the PBE were compared with the analytical solutions obtained by the ideal gas law. It was proven that the mesoscale formulations presented in this work were physically consistent with the macroscale modeling. It can be used to simulate large industrial plants when the compressibility induced bubble size variation is important.

Key words: Bubble column reactors, Computational fluid dynamics, Population balance equation, Compressibility

摘要： Bubble column reactors can be simulated by the two fluid model (TFM) coupled with the population balance equation (PBE). For the large industrial bubble columns, the compressibility due to the pressure difference may introduce notable bubble size variation. In order to address the compressibility effect, the PBE should be reformulated and coupled with the compressible TFM. In this work, the PBE with a compressibility term was formulated from single bubble dynamics, the mean Sauter diameters predicted by the compressible TFM coupled with the PBE were compared with the analytical solutions obtained by the ideal gas law. It was proven that the mesoscale formulations presented in this work were physically consistent with the macroscale modeling. It can be used to simulate large industrial plants when the compressibility induced bubble size variation is important.

关键词: Bubble column reactors, Computational fluid dynamics, Population balance equation, Compressibility

Dongyue Li, Zhipeng Li, Zhengming Gao. Compressibility induced bubble size variation in bubble column reactors: Simulations by the CFD-PBE[J]. Chin.J.Chem.Eng., 2018, 26(10): 2009-2013.

Dongyue Li, Zhipeng Li, Zhengming Gao. Compressibility induced bubble size variation in bubble column reactors: Simulations by the CFD-PBE[J]. Chinese Journal of Chemical Engineering, 2018, 26(10): 2009-2013.

References

[1] H. Jakobsen, H. Lindborg, C. Dorao, Modeling of bubble column reactors:Progress and limitations, Ind. Eng. Chem. Res. 44(2005) 5107-5151.

[2] D. Drew, Mathematical modeling of two-phase flow, Annu. Rev. Fluid Mech. 15(1982) 261-291.

[3] V. Buwa, V. Ranade, Mixing in bubble column reactors:Role of unsteady flow structures, Can. J. Chem. Eng. 81(2003) 402-411.

[4] M. Díaz, A. Iranzo, D. Cuadra, R. Barbero, F. Montes, M. Ga?an, Numerical simulation of the gas-liquid flow in a laboratory scale bubble column:Influence of bubble size distribution and non-drag forces, Chem. Eng. J. 139(2008) 363-379.

[5] I. Roghair, Y. Lau, N. Deen, H. Slagter, M. Baltussen, M. Annaland, J. Kuipers, On the drag force of bubbles in bubble swarms at intermediate and high Reynolds numbers, Chem. Eng. Sci. 66(2011) 3204-3211.

[6] A. Gupta, S. Roy, Euler-Euler simulation of bubbly flow in a rectangular bubble column:Experimental validation with Radioactive Particle Tracking, Chem. Eng. J. 225(2013) 818-836.

[7] Q. Xiao, N. Yang, J. Li, Stability-constrained multi-fluid CFD models for gas-liquid flow in bubble columns, Chem. Eng. Sci. 100(2013) 279-292.

[8] H. Jakobsen, Chemical Reactor Modeling:Multiphase Reactive Flows, Springer Science & Business Media, 2014.

[9] K. Guo, T. Wang, Y. Liu, J. Wang, CFD-PBM simulations of a bubble column with different liquid properties, Chem. Eng. J. 329(2017) 116-127.

[10] Q. Li, J. Cheng, C. Yang, Z. Mao, Simulation of a bubble column by computational fluid dynamics and population balance equation using the cell average method, Chem. Eng. Technol. 40(2017) 1792-1801.

[11] J. Cheng, C. Yang, M. Jiang, Q. Li, Z. Mao, Simulation of antisolvent crystallization in impinging jets with coupled multiphase flow-micromixing-PBE, Chem. Eng. Sci. 171(2017) 500-512.

[12] D. Ramkrishna, Population Balances:Theory and Applications to Particulate Systems in Engineering, Academic Press, 2000.

[13] D. Marchisio, R. Fox, Computational Models for Polydisperse Particulate and Multiphase Systems, Cambridge University Press, 2013.

[14] A. Buffo, M. Vanni, P. Renze, D. Marchisio, Empirical drag closure for polydisperse gas-liquid systems in bubbly flow regime:Bubble swarm and micro-scale turbulence, Chem. Eng. Res. Des. 113(2016) 284-303.

[15] X. Liang, H. Pan, Y. Su, Z. Luo, CFD-PBM approach with modified drag model for the gas-liquid flow in a bubble column, Chem. Eng. Res. Des. 112(2016) 88-102.

[16] L. Schiller, A. Naumann, A drag coefficient correlation, Z. Ver. Deutsch. Ing. 77(1935) 51-86.

[17] M. Lopez De Bertodano, W. Fullmer, A. Clausse, V. Ransom, Two-fluid Model Stability, Simulation and Chaos, Springer, 2016.

[18] D. Li, H. Christian, Simulation of bubbly flows with special numerical treatments of the semi-conservative and fully conservative two-fluid model, Chem. Eng. Sci. 174(2017) 25-39.

[19] E. Madadi-Kandjani, A. Passalacqua, An extended quadrature-based moment method with log-normal kernel density functions, Chem. Eng. Sci. 131(2015) 323-339.

[20] D. Lucas, E. Krepper, H. Prasser, Development of co-current air-water flow in a vertical pipe, Int. J. Multiphase Flow 31(2005) 1304-1328.