Ideality analysis and general laws of bubble swarm microflow for large-scale gas-liquid microreaction processes

doi:10.1016/j.cjche.2022.04.023

Chinese Journal of Chemical Engineering ›› 2022, Vol. 50 ›› Issue (10): 56-65.DOI: 10.1016/j.cjche.2022.04.023

• Fluid Dynamics and Transport Phenomena • Previous Articles Next Articles

Ideality analysis and general laws of bubble swarm microflow for large-scale gas-liquid microreaction processes

Lin Sheng, Yuchao Chen, Jian Deng, Guangsheng Luo

The State Key Laboratory of Chemical Engineering, Department of Chemical Engineering, Tsinghua University, Beijing 100084, China

Received:2022-02-10 Revised:2022-04-12 Online:2023-01-04 Published:2022-10-28
Contact: Guangsheng Luo,E-mail:gsluo@tsinghua.edu.cn
Supported by:
We gratefully acknowledge financial support from National Natural Science Foundation of China (21991104).

Ideality analysis and general laws of bubble swarm microflow for large-scale gas-liquid microreaction processes

Lin Sheng, Yuchao Chen, Jian Deng, Guangsheng Luo

The State Key Laboratory of Chemical Engineering, Department of Chemical Engineering, Tsinghua University, Beijing 100084, China

通讯作者: Guangsheng Luo,E-mail:gsluo@tsinghua.edu.cn
基金资助:
We gratefully acknowledge financial support from National Natural Science Foundation of China (21991104).

Abstract

Abstract: The flow ideality of bubbly microflow remains unclear even though it is vital for the design of microreactors, especially the ideality of bubble swarm microflow for large-scale gas-liquid microreaction processes. This work is the first time to report the ideality analysis of the microbubble swarm in a relatively large microchannel. The bubble swarm microflow has undergone two conditions: quasi-homogeneous plug flow and liquid phase/gas-liquid quasi-homogeneous phase two-phase laminar flow. Both the deviations of void fraction and bubble velocity from the ideal plug flow can divide into two parts, and the two transition points simultaneously happen at the velocity ratio of 1.25. There exists a critical capillary number to maintain the quasi-homogeneous plug flow, which could be regarded as the general laws for the design of gas-liquid microreactors. Finally, a novel model is developed to predict the bubble velocity. This work could be very helpful for the large-scale gas-liquid microreactors design.

Key words: Bubble swarm, Flow ideality, Viscous fluids, Gas-liquid microreactor

摘要： The flow ideality of bubbly microflow remains unclear even though it is vital for the design of microreactors, especially the ideality of bubble swarm microflow for large-scale gas-liquid microreaction processes. This work is the first time to report the ideality analysis of the microbubble swarm in a relatively large microchannel. The bubble swarm microflow has undergone two conditions: quasi-homogeneous plug flow and liquid phase/gas-liquid quasi-homogeneous phase two-phase laminar flow. Both the deviations of void fraction and bubble velocity from the ideal plug flow can divide into two parts, and the two transition points simultaneously happen at the velocity ratio of 1.25. There exists a critical capillary number to maintain the quasi-homogeneous plug flow, which could be regarded as the general laws for the design of gas-liquid microreactors. Finally, a novel model is developed to predict the bubble velocity. This work could be very helpful for the large-scale gas-liquid microreactors design.

关键词: Bubble swarm, Flow ideality, Viscous fluids, Gas-liquid microreactor

Lin Sheng, Yuchao Chen, Jian Deng, Guangsheng Luo. Ideality analysis and general laws of bubble swarm microflow for large-scale gas-liquid microreaction processes[J]. Chinese Journal of Chemical Engineering, 2022, 50(10): 56-65.

Lin Sheng, Yuchao Chen, Jian Deng, Guangsheng Luo. Ideality analysis and general laws of bubble swarm microflow for large-scale gas-liquid microreaction processes[J]. 中国化学工程学报, 2022, 50(10): 56-65.

References

[1] K. Wang, L.T. Li, P. Xie, G.S. Luo, Liquid-liquid microflow reaction engineering, React. Chem. Eng. 2 (5) (2017) 611-627
[2] J. Song, Y.J. Cui, L. Sheng, Y.J. Wang, C.C. Du, J. Deng, G.S. Luo, Determination of nitration kinetics of p-nitrotoluene with a homogeneously continuous microflow, Chem. Eng. Sci. 247 (2022) 117041
[3] Z.F. Yan, J.X. Tian, K. Wang, K.D.P. Nigam, G.S. Luo, Microreaction processes for synthesis and utilization of epoxides:A review, Chem. Eng. Sci. 229 (2021) 116071
[4] G.S. Luo, L. Du, Y.J. Wang, K. Wang, Manipulation and control of structure and size of inorganic nanomaterials in microchemical systems, Chem. Eng. Technol. 42 (10) (2019) 1996-2008
[5] G.S. Luo, L. Du, Y.J. Wang, K. Wang, Recent developments in microfluidic device-based preparation, functionalization, and manipulation of nano- and micro-materials, Particuology 45 (2019) 1-19
[6] J.S. Sui, J.Y. Yan, D. Liu, K. Wang, G.S. Luo, Continuous synthesis of nanocrystals via flow chemistry technology, Small 16 (15) (2020) e1902828
[7] K. Wang, G.S. Luo, Microflow extraction:A review of recent development, Chem. Eng. Sci. 169 (2017) 18-33
[8] H.H. Jeong, Z. Chen, S. Yadavali, J.H. Xu, D. Issadore, D. Lee, Large-scale production of compound bubbles using parallelized microfluidics for efficient extraction of metal ions, Lab Chip 19 (4) (2019) 665-673
[9] C. Zheng, B.C. Zhao, K. Wang, G.S. Luo, Determination of kinetics of CO₂ absorption in solutions of 2-amino-2-methyl-1-propanol using a microfluidic technique, AIChE J. 61 (12) (2015) 4358-4366
[10] J.S. Zhang, A.R. Teixeira, K.F. Jensen, Automated measurements of gas-liquid mass transfer in micropacked bed reactors, AIChE J. 64 (2) (2018) 564-570
[11] L. Sang, J.C. Tu, H. Cheng, G.S. Luo, J.S. Zhang, Hydrodynamics and mass transfer of gas-liquid flow in micropacked bed reactors with metal foam packing, AIChE J. 66 (2) (2020):e16803. https://doi.org/10.1002/aic.16803
[12] P.M.Y. Chung, M. Kawaji, The effect of channel diameter on adiabatic two-phase flow characteristics in microchannels, Int. J. Multiph. Flow 30 (7-8) (2004) 735-761
[13] C. Duan, Z.W. Liu, C.Y. Zhu, Y.G. Ma, T.T. Fu, Distribution of gas-liquid two-phase flow in parallel microchannels with the splitting of the liquid feed, Chem. Eng. J. 398 (2020) 125630
[14] Y.C. Chen, L. Sheng, J. Deng, G.S. Luo, Geometric effect on gas-liquid bubbly flow in capillary-embedded T-junction microchannels, Ind. Eng. Chem. Res. 60 (12) (2021) 4735-4744
[15] L. Sheng, L. Ma, Y.C. Chen, J. Deng, G.S. Luo, A comprehensive study of droplet formation in a capillary embedded step T-junction:From squeezing to jetting, Chem. Eng. J. 427 (2022) 132067
[16] 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
[17] A. Leclerc, M. Alamé, D. Schweich, P. Pouteau, C. Delattre, C. de Bellefon, Gas-liquid selective oxidations with oxygen under explosive conditions in a micro-structured reactor, Lab a Chip 8 (5) (2008) 814
[18] T. Yasukawa, W. Ninomiya, K. Ooyachi, N. Aoki, K. Mae, Enhanced production of ethyl pyruvate using gas-liquid slug flow in microchannel, Chem. Eng. J. 167 (2-3) (2011) 527-530
[19] M.Y. Pan, Z. Qian, L. Shao, M. Arowo, J.F. Chen, J.X. Wang, Absorption of carbon dioxide into N-methyldiethanolamine in a high-throughput microchannel reactor, Sep. Purif. Technol. 125 (2014) 52-58
[20] J. Deng, J.S. Zhang, K. Wang, G.S. Luo, Microreaction technology for synthetic chemistry, Chin. J. Chem. 37 (2) (2019) 161-170
[21] Z.F. Yan, J.X. Tian, C.C. Du, J. Deng, G.S. Luo, Reaction kinetics determination based on microfluidic technology, Chin. J. Chem. Eng. 41 (2022) 49-72
[22] A. Armand, The resistance during the movement of a two-phase system in horizontal pipes, Izv Vses. Tepl Inst. 1 (1946) 16-23
[23] M.I. Ali, M. Sadatomi, M. Kawaji, Adiabatic two-phase flow in narrow channels between two flat plates, Can. J. Chem. Eng. 71 (5) (1993) 657-666
[24] R.Q. Xiong, J.N. Chung, An experimental study of the size effect on adiabatic gas-liquid two-phase flow patterns and void fraction in microchannels, Phys. Fluids 19 (3) (2007) 033301
[25] T. Fukano, A. Kariyasaki, Characteristics of gas-liquid two-phase flow in a capillary tube, Nucl. Eng. Des. 141 (1-2) (1993) 59-68
[26] K. Mishima, T. Hibiki, Some characteristics of air-water two-phase flow in small diameter vertical tubes, Int. J. Multiph. Flow 22 (4) (1996) 703-712
[27] C.W. Choi, D.I. Yu, M.H. Kim, Adiabatic two-phase flow in rectangular microchannels with different aspect ratios:Part II-bubble behaviors and pressure drop in single bubble, Int. J. Heat Mass Transf. 53 (23-24) (2010) 5242-5249
[28] H. Liu, C.O. Vandu, R. Krishna, Hydrodynamics of Taylor flow in vertical capillaries:Flow regimes, bubble rise velocity, liquid slug length, and pressure drop, Ind. Eng. Chem. Res. 44 (14) (2005) 4884-4897
[29] A. Kawahara, M. Sadatomi, K. Nei, H. Matsuo, Experimental study on bubble velocity, void fraction and pressure drop for gas-liquid two-phase flow in a circular microchannel, Int. J. Heat Fluid Flow 30 (5) (2009) 831-841
[30] A. Kawahara, M. Sadatomi, K. Nei, H. Matsuo, Characteristics of two-phase flows in a rectangular microchannel with a T-junction type gas-liquid mixer, Heat Transf. Eng. 32 (7-8) (2011) 585-594
[31] Y.T. Lu, T.T. Fu, C.Y. Zhu, Y.G. Ma, H.Z. Li, Scaling of the bubble formation in a flow-focusing device:Role of the liquid viscosity, Chem. Eng. Sci. 105 (2014) 213-219
[32] C. Zhang, T.T. Fu, C.Y. Zhu, S.K. Jiang, Y.G. Ma, H.Z. Li, Dynamics of bubble formation in highly viscous liquids in a flow-focusing device, Chem. Eng. Sci. 172 (2017) 278-285
[33] L. Sheng, Y.C. Chen, J. Deng, G.S. Luo, High-frequency formation of bubble with short length in a capillary embedded step T-junction microdevice, AIChE J. 67 (11) (2021) e17376
[34] L. Sheng, Y. Chang, J. Deng, G.S. Luo, Taylor bubble generation rules in liquids with a higher viscosity in a T-junction microchannel, Ind. Eng. Chem. Res. 61 (6) (2022) 2623-2632
[35] H.H. Jeong, V.R. Yelleswarapu, S. Yadavali, D. Issadore, D. Lee, Kilo-scale droplet generation in three-dimensional monolithic elastomer device (3D MED), Lab Chip 15 (23) (2015) 4387-4392
[36] H.H. Jeong, S. Yadavali, D. Issadore, D. Lee, Liter-scale production of uniform gas bubbles via parallelization of flow-focusing generators, Lab Chip 17 (15) (2017) 2667-2673
[37] Y.J. Cui, Y.K. Li, K. Wang, J. Deng, G.S. Luo, High-throughput preparation of uniform tiny droplets in multiple capillaries embedded stepwise microchannels, J. Flow Chem. 10 (1) (2020) 271-282
[38] L. Sheng, Y.C. Chen, K. Wang, J. Deng, G.S. Luo, General rules of bubble formation in viscous liquids in a modified step T-junction microdevice, Chem. Eng. Sci. 239 (2021) 116621
[39] P. Garstecki, G.M. Whitesides, Flowing crystals:Nonequilibrium structure of foam, Phys. Rev. Lett. 97 (2) (2006) 024503
[40] J.P. Raven, P. Marmottant, Microfluidic crystals:Dynamic interplay between rearrangement waves and flow, Phys Rev Lett 102 (8) (2009) 084501
[41] A. van der Net, G.W. Delaney, W. Drenckhan, D. Weaire, S. Hutzler, Crystalline arrangements of microbubbles in monodisperse foams, Colloids Surf. A Physicochem. Eng. Aspects 309 (1-3) (2007) 117-124

Ideality analysis and general laws of bubble swarm microflow for large-scale gas-liquid microreaction processes

Ideality analysis and general laws of bubble swarm microflow for large-scale gas-liquid microreaction processes

PDF (PC)

Knowledge

Abstract

Cite this article

share this article

References

Related Articles 0

Recommended Articles

Metrics

Comments