Mass transfer intensification and mechanism analysis of gas–liquid two-phase flow in the microchannel embedding triangular obstacles

doi:10.1016/j.cjche.2021.09.016

Abstract

Abstract: An effective mass transfer intensification method was proposed by embedding different triangular obstacles to improve the gas–liquid mass transfer efficiency in microchannel. The influences of triangle obstacles configuration, obstacle interval and flow rate on the volumetric mass transfer coefficient, pressure drop and energy consumption were investigated experimentally. The enhancement factor was used to quantify the mass transfer enhancement effect of triangle obstacles. It was found that the isosceles or equilateral triangle obstacles are superior to the rectangular obstacles. The maximum enhancement factor of equilateral triangle obstacles was 2.35. Considering comprehensively mass transfer enhancement and energy consumption, the isosceles triangle obstacle showed the best performance, its maximum enhancement factor was 2.1, while the maximum pressure drop increased only 0.41 kPa (22%) compared to the microchannel without obstacles. Furthermore, a micro-particle image velocimetry (micro-PIV) was utilized to observe the flow field distribution and evolution, in order to understand and analyze the enhancement mechanism. The micro-PIV measurement indicated that the obstacle structure could induce the formation of vortex, which promotes convective mass transfer and thins the flow boundary layer, accordingly, the gas–liquid mass transfer efficiency is remarkably improved. This study can provide theoretical guidance and support for the design and optimization of microchannel with triangular obstacles.

Key words: Enhancement factor, Microchannels, Gas–liquid flow, Mass transfer, Triangular obstacle

摘要： An effective mass transfer intensification method was proposed by embedding different triangular obstacles to improve the gas–liquid mass transfer efficiency in microchannel. The influences of triangle obstacles configuration, obstacle interval and flow rate on the volumetric mass transfer coefficient, pressure drop and energy consumption were investigated experimentally. The enhancement factor was used to quantify the mass transfer enhancement effect of triangle obstacles. It was found that the isosceles or equilateral triangle obstacles are superior to the rectangular obstacles. The maximum enhancement factor of equilateral triangle obstacles was 2.35. Considering comprehensively mass transfer enhancement and energy consumption, the isosceles triangle obstacle showed the best performance, its maximum enhancement factor was 2.1, while the maximum pressure drop increased only 0.41 kPa (22%) compared to the microchannel without obstacles. Furthermore, a micro-particle image velocimetry (micro-PIV) was utilized to observe the flow field distribution and evolution, in order to understand and analyze the enhancement mechanism. The micro-PIV measurement indicated that the obstacle structure could induce the formation of vortex, which promotes convective mass transfer and thins the flow boundary layer, accordingly, the gas–liquid mass transfer efficiency is remarkably improved. This study can provide theoretical guidance and support for the design and optimization of microchannel with triangular obstacles.

关键词: Enhancement factor, Microchannels, Gas–liquid flow, Mass transfer, Triangular obstacle

Xuanyu Nie, Chunying Zhu, Taotao Fu, Youguang Ma. Mass transfer intensification and mechanism analysis of gas–liquid two-phase flow in the microchannel embedding triangular obstacles[J]. Chinese Journal of Chemical Engineering, 2022, 51(11): 100-108.

References

[1] D. Gómez-Díaz, J.M. Navaza, Gas/liquid mass transfer in carbon dioxide-alkanes mixtures, Chem. Eng. J. 114 (1-3) (2005) 131-137
[2] D.P. Rao, A. Bhowal, P.S. Goswami, Process intensification in rotating packed beds (HIGEE):An appraisal, Ind. Eng. Chem. Res. 43 (4) (2004) 1150-1162
[3] N.H. Yang, Y.J. Chen, C.C. Liao, T.W. Chung, Improved absorption ingas-liquid systems by the addition of a low surface tension component in the gas and/or liquid phase, Ind. Eng. Chem. Res. 47 (22) (2008) 8823-8827
[4] Y.M. Li, Y.S. Lu, X.J. Liu, G.Q. Wang, Y. Nie, J.B. Ji, Mass-transfer characteristics in a rotating zigzag bed as a Higee device, Sep. Purif. Technol. 186 (2017) 156-165
[5] D.X. Deng, L. Zeng, W. Sun, G. Pi, Y. Yang, Experimental study of flow boiling performance of open-ring pin fin microchannels, Int. J. Heat Mass Transf. 167 (2021) 120829
[6] P. Sobieszuk, R. Pohorecki, P. Cygański, J. Grzelka, Determination of the interfacial area and mass transfer coefficients in the Taylor gas-liquid flow in a microchannel, Chem. Eng. Sci. 66 (23) (2011) 6048-6056
[7] S. Waelchli, P. Rudolf von Rohr, Two-phase flow characteristics in gas-liquid microreactors, Int. J. Multiph. Flow 32 (7) (2006) 791-806
[8] A.D. Stroock, S.K. Dertinger, A. Ajdari, I. Mezic, H.A. Stone, G.M. Whitesides, Chaotic mixer for microchannels, Science 295 (5555) (2002) 647-651
[9] T. Thorsen, R.W. Roberts, F.H. Arnold, S.R. Quake, Dynamic pattern formation in a vesicle-generating microfluidic device, Phys. Rev. Lett. 86 (18) (2001) 4163-4166
[10] C.Q. Yao, Z.Y. Dong, Y.C. Zhao, G.W. Chen, An online method to measure mass transfer of slug flow in a microchannel, Chem. Eng. Sci. 112 (2014) 15-24
[11] W. Chen, S.Y. Chen, X.G. Yuan, H.S. Zhang, B.T. Liu, K. Yu, PIV measurement for Rayleigh convection and its effect on mass transfer, Chin. J. Chem. Eng. 22 (10) (2014) 1078-1086
[12] T. Dehghani, F. Sadegh Moghanlou, M. Vajdi, M. Shahedi Asl, M. Shokouhimehr, M. Mohammadi, Mixing enhancement through a micromixer using topology optimization, Chem. Eng. Res. Des. 161 (2020) 187-196
[13] Z.Z. Che, N.T. Nguyen, T.N. Wong, Analysis of chaotic mixing in plugs moving in meandering microchannels, Phys. Rev. E 84 (6) (2011) 066309
[14] C.Y. Wu, R.T. Tsai, Fluid mixing via multidirectional vortices in converging-diverging meandering microchannels with semi-elliptical side walls, Chem. Eng. J. 217 (2013) 320-328
[15] W.P. Zhang, X. Wang, X. Feng, C. Yang, Z.S. Mao, Investigation of mixing performance in passive micromixers, Ind. Eng. Chem. Res. 55 (38) (2016) 10036-10043
[16] Y.F. Guan, B.C. Sun, Versatile microfluidic mixing platform for high- and low-viscosity liquids via acoustic and chemical microbubbles, Micromachines 10 (12) (2019) E854
[17] H.S. Seo, Y.J. Kim, A study on the mixing characteristics in a hybrid type microchannel with various obstacle configurations, Mater. Res. Bull. 47 (10) (2012) 2948-2951
[18] S. Sarkar, K.K. Singh, V. Shankar, K.T. Shenoy, CFD simulations to study the effects of wall protrusions on microfluidic mixing, J. Micromech. Microeng. 25 (8) (2015) 084008
[19] H.S. Santana, J.L. SilvaJr, O.P. TarantoJr, Optimization of micromixer with triangular baffles for chemical process in millidevices, SensorActuat. B:Chem. 281 (2019) 191-203
[20] Y.R. Yin, C.Y. Zhu, T.T. Fu, Y.G. Ma, K. Wang, G.S. Luo, Enhancement effect and mechanism of gas-liquid mass transfer by baffles embedded in the microchannel, Chem. Eng. Sci. 201 (2019) 264-273
[21] S.Z. Zhang, C.Y. Zhu, H.S. Feng, T.T. Fu, Y.G. Ma, Intensification of gas-liquid two-phase flow and mass transfer in microchannels by sudden expansions, Chem. Eng. Sci. 229 (2021) 116040
[22] W.G. Whitman, The two film theory of gas absorption, Int. J. Heat Mass Transf. 5 (5) (1962) 429-433
[23] C.H. Sun, Z. Ning, X.Q. Qiao, M. Lv, J. Fu, J. Zhao, X.T. Wang, Numerical simulation of gas-liquid flow behavior in the nozzle exit region of an effervescent atomizer, Int. J. Spray Combust. Dyn. 11 (2019) 175682771882159
[24] F. Reichmann, A. Tollkötter, S. Körner, N. Kockmann, Gas-liquid dispersion in micronozzles and microreactor design for high interfacial area, Chem. Eng. Sci. 169 (2017) 151-163
[25] H.W. Jia, P. Zhang, Investigation of the Taylor bubble under the effect of dissolution in microchannel, Chem. Eng. J. 285 (2016) 252-263
[26] A.L. Dessimoz, P. Raspail, C. Berguerand, L. Kiwi-Minsker, Quantitative criteria to define flow patterns in micro-capillaries, Chem. Eng. J. 160 (3) (2010) 882-890
[27] D.F. Ma, C.Y. Zhu, T.T. Fu, X.G. Yuan, Y.G. Ma, An effective hybrid solvent of MEA/DEEA for CO₂ absorption and its mass transfer performance in microreactor, Sep. Purif. Technol. 242 (2020) 116795
[28] V. van Steijn, M.T. Kreutzer, C.R. Kleijn, μ-PIV study of the formation of segmented flow in microfluidic T-junctions, Chem. Eng. Sci. 62 (24) (2007) 7505-7514
[29] C.Q. Yao, Z.Y. Dong, Y.C. Zhang, Y. Mi, Y.C. Zhao, G.W. Chen, On the leakage flow around gas bubbles in slug flow in a microchannel, AIChE J. 61 (11) (2015) 3964-3972
[30] V. Mengeaud, J. Josserand, H.H. Girault, Mixing processes in a zigzag microchannel:Finite element simulations and optical study, Anal. Chem. 74 (16) (2002) 4279-4286
[31] D.D. Ma, G.D. Xia, L.X. Zong, Y.T. Jia, Y.X. Tang, R.P. Zhi, Experimental investigation of flow boiling heat transfer performance in zigzag microchannel heat sink for electronic cooling devices, Int. J. Therm. Sci. 145 (2019) 106003
[32] D.D. Ma, G.D. Xia, Y.F. Li, Y.T. Jia, J. Wang, Effects of structural parameters on fluid flow and heat transfer characteristics in microchannel with offset zigzag grooves in sidewall, Int. J. Heat Mass Transf. 101 (2016) 427-435
[33] L.S. Yang, M.H. Xu, J.J. Wang, L. Song, J.X. Wang, Experimental and numerical analysis of a demister with vortex generators, Chin. J. Chem. Eng. 33 (2021) 83-95
[34] C.H. Tai, R.J. Yang, M.Z. Huang, C.W. Liu, C.H. Tsai, L.M. Fu, Micromixer utilizing electrokinetic instability-induced shedding effect, Electrophoresis 27 (24) (2006) 4982-4990
[35] S.Y. Chen, T. Zhang, L. Lv, Y.X. Chen, Y.C. Yang, S.W. Tang, Intensification of the liquid side mass transfer in double-side falling film microchannels by micro-mixing structures, Chem. Eng. Sci. 193 (2019) 264-275
[36] C.C. Cho, C.O.K. Chen, H.T. Yau, Mixing of electrokinetically-driven power-law fluids in zigzag microchannels, Int. J. Numer. Methods Heat Fluid Flow, 25(2) (2015) 391-399
[37] Y.R. Yin, R.W. Guo, C.Y. Zhu, T.T. Fu, Y.G. Ma, Enhancement of gas-liquid mass transfer in microchannels by rectangular baffles, Sep. Purif. Technol. 236 (2020) 116306
[38] G.Y. Lin, S. Jiang, C.Y. Zhu, T.T. Fu, Y.G. Ma, Mass-transfer characteristics of CO₂ absorption into aqueous solutions of N-methyldiethanolamine +diethanolamine in a T-junction microchannel, ACS Sustain. Chem. Eng. 7 (4) (2019) 4368-4375
[39] C.Q. Yao, Y.C. Zhao, C.B. Ye, M.H. Dang, Z.Y. Dong, G.W. Chen, Characteristics of slug flow with inertial effects in a rectangular microchannel, Chem. Eng. Sci. 95 (2013) 246-256
[40] P. Zhang, C.Q. Yao, H.Y. Ma, N. Jin, X.L. Zhang, H. Lü, Y.C. Zhao, Dynamic changes in gas-liquid mass transfer during Taylor flow in long serpentine square microchannels, Chem. Eng. Sci. 182 (2018) 17-27
[41] H. Ganapathy, A. Shooshtari, S. Dessiatoun, M. Alshehhi, M. Ohadi, Fluid flow and mass transfer characteristics of enhanced CO₂ capture in a minichannel reactor, Appl. Energy 119 (2014) 43-56
[42] G. Singh, R. Lakkaraju, Wall-mounted flexible plates in a two-dimensional channel trigger early flow instabilities, Phys. Rev. E 100 (2) (2019) 023109
[43] G.F. Lu, J.R. Yang, X.Q. Zhai, X.L. Wang, Hotspot thermal management in microchannel heat sinks with vortex generators, Int. J. Therm. Sci. 161 (2021) 106727
[44] M.J. Nieves-Remacha, A.A. Kulkarni, K.F. Jensen, Gas-liquid flow and mass transfer in an advanced-flow reactor, Ind. Eng. Chem. Res. 52 (26) (2013) 8996-9010
[45] Y.R. Yin, C.Y. Zhu, R.W. Guo, T.T. Fu, Y.G. Ma, Gas-liquid two-phase flow in a square microchannel with chemical mass transfer:Flow pattern, void fraction and frictional pressure drop, Int. J. Heat Mass Transf. 127 (2018) 484-496
[46] J. Yue, G.W. Chen, Q. Yuan, L.G. Luo, Y. Gonthier, Hydrodynamics and mass transfer characteristics in gas-liquid flow through a rectangular microchannel, Chem. Eng. Sci. 62 (7) (2007) 2096-2108
[47] A.E. Dukler, M.G. Hubbard, A model for gas-liquid slug flow in horizontal and near horizontal tubes, Ind. Eng. Chem. Res. 14 (4) (1975) 337-347