Effect of swirling addition on the liquid mixing performance in a T-jets mixer

doi:10.1016/j.cjche.2022.07.008

Abstract

Abstract: Swirling addition to the stream is beneficial for the fluid mixing. This work aims to study the mixing process intensification in a conventional T-jets mixer by the swirling addition. After experimental verification by the planar laser-induced fluorescence technique, large eddy simulation with the dynamic kinetic energy sub-grid stress model is used to predict how the swirling strength (in terms of swirling number, S_w) and swirling directions affect the mixing performance, e.g. the tracer concentration distribution, mixing time, and turbulent characteristics in the T-jets mixers. Predictions show that the swirling strength is the key factor affecting the mixing efficiency of the process. The overall mixing time, τ₉₀, can be significantly reduced by increasing S_w. Vortex analysis shows that more turbulent eddies appear in the collision zone and the turbulent kinetic energy dissipation rate increases obviously with the swirling addition. When S_w is kept constant, the mixing process can be accelerated and intensified by adding swirling to only one stream, to both streams with the opposite swirling directions, or to both streams with the same swirling directions. Amplification of the mixing process by enlarging the mixer size or increasing the flow rates is also optimized. Thus, this work provides a new strategy to improve the mixing performance of the traditional T-jets mixers by the swirling addition.

Key words: Mixing, T-jets mixer, Swirling, Computational fluid dynamics (CFD), Large eddy simulation

摘要： Swirling addition to the stream is beneficial for the fluid mixing. This work aims to study the mixing process intensification in a conventional T-jets mixer by the swirling addition. After experimental verification by the planar laser-induced fluorescence technique, large eddy simulation with the dynamic kinetic energy sub-grid stress model is used to predict how the swirling strength (in terms of swirling number, S_w) and swirling directions affect the mixing performance, e.g. the tracer concentration distribution, mixing time, and turbulent characteristics in the T-jets mixers. Predictions show that the swirling strength is the key factor affecting the mixing efficiency of the process. The overall mixing time, τ₉₀, can be significantly reduced by increasing S_w. Vortex analysis shows that more turbulent eddies appear in the collision zone and the turbulent kinetic energy dissipation rate increases obviously with the swirling addition. When S_w is kept constant, the mixing process can be accelerated and intensified by adding swirling to only one stream, to both streams with the opposite swirling directions, or to both streams with the same swirling directions. Amplification of the mixing process by enlarging the mixer size or increasing the flow rates is also optimized. Thus, this work provides a new strategy to improve the mixing performance of the traditional T-jets mixers by the swirling addition.

关键词: Mixing, T-jets mixer, Swirling, Computational fluid dynamics (CFD), Large eddy simulation

Chunhui Li, Bin Wu, Junjie Zhang, Peicheng Luo. Effect of swirling addition on the liquid mixing performance in a T-jets mixer[J]. Chinese Journal of Chemical Engineering, 2022, 50(10): 108-116.

Chunhui Li, Bin Wu, Junjie Zhang, Peicheng Luo. Effect of swirling addition on the liquid mixing performance in a T-jets mixer[J]. 中国化学工程学报, 2022, 50(10): 108-116.

References

[1] M.S.C.A. Brito, L.P. Esteves, C.P. Fonte, M.M. Dias, J.C.B. Lopes, R.J. Santos, Mixing of fluids with dissimilar viscosities in Confined Impinging Jets, Chem. Eng. Res. Des. 134 (2018) 392-404
[2] Y. Berman, A. Tanklevsky, Y. Oren, A. Tamir, Modeling and experimental studies of SO₂ absorption in coaxial cylinders with impinging streams:Part I, Chem. Eng. Sci. 55 (5) (2000) 1009-1021
[3] Y. Dong, W.K. Ng, S. Shen, S. Kim, R.B. Tan, Controlled antisolvent precipitation of spironolactone nanoparticles by impingement mixing, Int. J. Pharm. 410 (1-2) (2011) 175-179
[4] B.T. Wang, Y.C. Chen, J.B. Cai, J.L. Zhao, C.F. Ma, Experimental investigation of circular submerged jet impingement heat transfer with mixed molten salt, Exp. Therm. Fluid Sci. 98 (2018) 30-37
[5] M. Icardi, E. Gavi, D.L. Marchisio, A.A. Barresi, M.G. Olsen, R.O. Fox, D. Lakehal, Investigation of the flow field in a three-dimensional Confined Impinging Jets Reactor by means of microPIV and DNS, Chem. Eng. J. 166 (1) (2011) 294-305
[6] W.F. Li, Y. Wei, G.Y. Tu, Z.H. Shi, H.F. Liu, F.C. Wang, Experimental study about mixing characteristic and enhancement of T-jet reactor, Chem. Eng. Sci. 144 (2016) 116-125
[7] W.F. Li, K.J. Du, G.S. Yu, H.F. Liu, F.C. Wang, Experimental study of flow regimes in three-dimensional confined impinging jets reactor, AIChE J. 60 (8) (2014) 3033-3045
[8] Z.M. Gao, J. Han, Y.D. Xu, Y.Y. Bao, Z.P. Li, Particle image velocimetry (PIV) investigation of flow characteristics in confined impinging jet reactors, Ind. Eng. Chem. Res. 52 (33) (2013) 11779-11786
[9] Y. Liu, R.O. Fox, CFD predictions for chemical processing in a confined impinging-jets reactor, AIChE J. 52 (2) (2006) 731-744
[10] S. Pal, K. Madane, M. Mane, A.A. Kulkarni, Impingement dynamics of jets in a confined impinging jet reactor, Ind. Eng. Chem. Res. 60 (2) (2021) 969-979
[11] A. Nie, Z.M. Gao, L. Xue, Z.Q. Cai, G.M. Evans, A. Eaglesham, Micromixing performance and the modeling of a confined impinging jet reactor/high speed disperser, Chem. Eng. Sci. 184 (2018) 14-24
[12] M. Engler, N. Kockmann, T. Kiefer, P. Woias, Numerical and experimental investigations on liquid mixing in static micromixers, Chem. Eng. J. 101 (1-3) (2004) 315-322
[13] S.H. Wong, M.C.L. Ward, C.W. Wharton, Micro T-mixer as a rapid mixing micromixer, Sens. Actuat. B Chem. 100 (3) (2004) 359-379
[14] Y.C. Zhao, G.W. Chen, Q. Yuan, Liquid-liquid two-phase mass transfer in the T-junction microchannels, AIChE J. 53 (12) (2007) 3042-3053
[15] R.J. Santos, M.A. Sultan, State of the art of mini/micro jet reactors, Chem. Eng. Technol. 36 (6) (2013) 937-949
[16] A.O. El Moctar, N. Aubry, J. Batton, Electro-hydrodynamic micro-fluidic mixer, Lab Chip 3 (4) (2003) 273-280
[17] T. Frommelt, M. Kostur, M. Wenzel-Schäfer, P. Talkner, P. Hänggi, A. Wixforth, Microfluidic mixing via acoustically driven chaotic advection, Phys. Rev. Lett. 100 (3) (2008) 034502
[18] H.H. Himstedt, Q. Yang, L.P. Dasi, X.H. Qian, S.R. Wickramasinghe, M. Ulbricht, Magnetically activated micromixers for separation membranes, Langmuir 27 (9) (2011) 5574-5581
[19] V. Hessel, H. Löwe, F. Schönfeld, Micromixers-A review on passive and active mixing principles, Chem. Eng. Sci. 60 (8-9) (2005) 2479-2501
[20] T. Takano, Y. Ikarashi, K. Uchiyama, T. Yamagata, N. Fujisawa, Influence of swirling flow on mass and momentum transfer downstream of a pipe with elbow and orifice, Int. J. Heat Mass Transf. 92 (2016) 394-402
[21] Y.M. Xi, J.Z. Yu, Y.Q. Xie, H.X. Gao, Single-phase flow and heat transfer in swirl microchannels, Exp. Therm. Fluid Sci. 34 (8) (2010) 1309-1315
[22] A.S. Lobasov, S.V. Alekseenko, D.M. Markovich, V.M. Dulin, Mass and momentum transport in the near field of swirling turbulent jets. Effect of swirl rate, Int. J. Heat Fluid Flow 83 (2020) 108539
[23] B. Wu, C.H. Li, M.X. Zhang, P.C. Luo, Liquid mixing intensification by adding swirling flow in the transverse jet mixer, AIChE J. 67 (8) (2021) e17276
[24] C.H. Li, J.J. Zhang, J.Z. He, P.C. Luo, Gas-liquid hydrodynamics in a self-suction jet reactor with or without swirling addition, Chem. Eng. Sci. 247 (2022) 117059
[25] P.C. Luo, H.Y. Jia, C.X. Xin, G.Z. Xiang, Z. Jiao, H. Wu, An experimental study of liquid mixing in a multi-orifice-impinging transverse jet mixer using PLIF, Chem. Eng. J. 228 (2013) 554-564
[26] W.W. Kim, S. Menon, W.W. Kim, S. Menon, Application of the localized dynamic subgrid-scale model to turbulent wall-bounded flows, Proceedings of the 35th Aerospace Sciences Meeting and Exhibit, AIAA, Reno, NV. Reston, Virginia, 1997, 210
[27] P.C. Luo, Y. Fang, B. Wu, H. Wu, Turbulent characteristics and design of transverse jet mixers with multiple orifices, Ind. Eng. Chem. Res. 55 (32) (2016) 8858-8868
[28] F. Ghasempour, R. Andersson, B. Andersson, Identification and characterization of three-dimensional turbulent flow structures, AIChE J. 62 (4) (2016) 1265-1277
[29] N.A. Chigier, J.M. Beér, Velocity and static-pressure distributions in swirling air jets issuing from annular and divergent nozzles, J. Fluids Eng. 86 (4) (1964) 788-796
[30] I.K. Toh, D. Honnery, J. Soria, Axial plus tangential entry swirling jet, Exp. Fluids 48 (2) (2010) 309-325
[31] S. Skripkin, M. Tsoy, S. Shtork, K. Hanjalić, Comparative analysis of twin vortex ropes in laboratory models of two hydro-turbine draft-tubes, J. Hydraul. Res. 54 (4) (2016) 450-460
[32] F. Ghasempour, R. Andersson, B. Andersson, Multidimensional turbulence spectra-Statistical analysis of turbulent vortices, Appl. Math. Model. 38 (17-18) (2014) 4226-4237