Lattice boltzmann simulation of gas-liquid flow in serpentine microchannel under different contact angle

doi:10.16085/j.issn.1000-6613.2016.s1.004

Abstract

Abstract: In order to study the gas-liquid two-phase flow of 90° Y-junction convergence coil, the method of lattice Boltzmann was adopted.The simulation of gas-liquid two-phase flow with air and water as working fluid was carried out in the serpentine microchannels of rectangular cross section.After passing the verification experiment, according to the calculation results, the flow patterns of different contact angles are plotted with the gas-liquid phase velocity as the coordinate and the effect of contact angle on slug flow was in-depth studied;Meanwhile, the difference of pressure drop and friction factor of two-phase flow under different contact angle in serpentine microchannels were compared; Influence factors of wall friction coefficient and shear stress were also discussed.It showed that hydrophobic wall which means the contact angle is greater than 90 degrees, the two-phase flow pressure drop, friction factor, wall friction coefficient and wall shear stress were lower than related parameters in serpentine microchannel with hydrophilic wall, which is beneficial to fluid flow.

Key words: serpentine microchannels, gas-liquid flow, numerical simulation, lattice Boltzmann, hydrodynamics

摘要： 在90°Y形汇流的矩形截面蛇形微通道内,采用格子Boltzmann方法对不同接触角的蛇形微通道内气液两相流动进行了数值计算。首先以空气和水为工作流体对气液两相流动进行模拟研究并通过实验进行验证。验证模型合理性后,根据模拟计算结果,以气液相流速为坐标绘制了不同接触角下的流型图并分析其差异性及原因;同时深入研究了液相黏度和接触角对于弹状流流体力学性质的综合影响;比较了具有不同接触角壁面的蛇形微通道内两相流压降、摩擦因子、壁面摩擦系数和剪切应力的分布规律,并讨论了蛇形微通道内气液两相流动的影响因素。研究表明疏水壁面即接触角大于90°时,微通道内两相流压降、摩擦因子、壁面摩擦系数和剪切应力均低于亲水壁面微通道内相关参数,更利于流体流动。

关键词: 蛇形微通道, 气液两相流, 数值模拟, 格子玻尔兹曼, 流体动力学

CLC Number:

TK172

ZHOU Yun, CHANG He. Lattice boltzmann simulation of gas-liquid flow in serpentine microchannel under different contact angle[J]. Chemical Industry and Engineering Progree, 2016, 35(S1): 20-25.

周云龙, 常赫. 壁面润湿性对蛇形微通道内两相流流动特性影响的格子Boltzmann模拟[J]. 化工进展, 2016, 35(S1): 20-25.

References

[1] FIGEYS Daneil,PINTO Devannand.Lab-on-a chip:a revolution in biological and medical sciences[J].Analytical Chemistry, 2000,72(9):330A-335A.
[2] EHRFELD Wolfgang,VOLKER Hessel, LOWE Holger. Microreactors:new technology for modern chemistry[M]. Weinheim:Wiley-VCH,2001.
[3] MAS de Nuria,JACKMAN Rebecca,MARTIN Schmidt,et al. Microchemical systems for direct fluorination of aromatics//Fifth International Conference on Microreaction Technology (IMRET5)[C].Berlin:Springer-Verlag,2001:60-67.
[4] 林宗虎.气液两相流和沸腾传热[M].西安:西安交通大学出版社, 2003.
[5] 施明恒,甘永平,马重芳.沸腾和凝结[M].北京:高等教育出版社,1995.
[6] LEE Chi Yong,LEE Sang Yong.Influence of surface wettability on transition of two-phase flow pattern in round mini-channels[J]. International Journal of Multiphase Flow,2008, 34(7):706-711.
[7] TRIPLETT K A, GHIAASIAAN S M, ABDEL-KHALIK S I,et al.Gas-liquid two-phase flow in microchannels Part Ⅰ:Two-phase flow patterns[J]. International Journal of Multiphase Flow, 1999,25(3):377-394.
[8] SERIZAWA Akimi, FENG Ziping,KAWARA Zensaku. Two-phase flow in microchannels[J].Experimental Thermal and Fluid Science, 2002,26(6/7):703-714.
[9] CHOI Chiwoong,YU Dongin,KIM Moohwan.Surface wettability effect on flow pattern and pressure drop in adiabatic two-phase flows in rectangular microchannels with T-junction mixer[J].Experimental Thermal and Fluid Science,2011,35(6):1086-1096.
[10] GUAN Ning, LIU Zhigang, JIANG Guilin, et al. Experimental and theoretical investigations on the flow resistance reduction and slip flow in super-hydrophobic micro tubes tubes[J]. Experimental Thermal and Fluid Science,2015,69(3):45-57.
[11] 孙俊杰,郝婷婷,马虎兰,等.壁面润湿性对微通道内二氧化碳-水两相流流动及传质性能的影响[J].化工学报,2015,66(9):3405-3412.
[12] ZHU Xiaoyang, ZHU Liu, CHEN Hejuan, et al.Fabrication of multi-scale micro-lens arrays on hydrophobic surfaces using a drop-on-demand droplet generator[J].Optics and Laser Technology,2015,66(8):156-165.
[13] MA Minglin,HILL Randal.Superhydrophobic surfaces[J]. Current Opinion in Colloid and Interface Science,2006,11(4):193-202.
[14] WU Yan,GAO Shengdong.Developent of free adjustable function generator for drop-on-demand droplets generation[C].Berlin Herdelberg:Springer,2012:477-481.
[15] CHEN Weichih, WU Tsungju,WU Wenjong,et al. Fabrication of inkjet-printed SU-8 photoresist microlens using hydrophilic confinement[J]. Journal of Micromechanics and Microengineering,2013, 23(6):65008-65015.
[16] KIM Yeon, PFEIFFER Karl,VOIGT Anja,et al.Directly fabricated multi-scale microlens arrays on a hydrophobic flat surface by a simple ink-jet printing technique[J].Journal of Materials Chemostry,2012,22(7):3053-3058.
[17] HE Xiaoyi, CHEN Shiyi, DOOLEN Gary.A novel thermal model for the lattice Boltzmann method in incompressible limit[J].Journal of Computational Physics,1998,146(1):282-300.
[18] 周云龙,孙振国.蛇形微通道气液两相流动特性[J].化工学报,2015,66(11):4350-4358.
[19] QIAN Dongying, LAWAL Adeniyi.Numerical study on gas and liquid slugs for Taylor flow in a T-junction microchannel[J].Chemical Engineering Science,2006,61(23):7609-7625.
[20] OU Jia,ROTHSTEIN Jonathan.Direct velocity measureme-nts of the flow past drag-reducing ultra hydrophobic surfaces[J].Physics of Fluids,2015,17(10):3379-3392.
[21] 黄桥高,潘光,宋保维.疏水表面滑移流动及减阻特性的格子Boltzmann方法模拟[J].物理学报,2014,63(5):1-7.