Gas–liquid two-phase flow in serpentine microchannel with different wall wettability 被引量：8

Gas–liquid two-phase flow in serpentine microchannel with different wall wettability

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摘要 Gas–liquid flow in serpentine microchannel with different surface properties exhibits drastically different flow behavior. With water and air as working fluids, the method of numerical simulation was adopted in this paper based on CLSVOF(coupled level set and volume of fluid method) multiphase model. After verifying the reasonability of the model through experiment, by changing wall properties and Re number(Re<1500), the influences of contact angle and surface roughness on flow regime and Po number were discussed. Moreover, the difference of pressure drop between curve and straight microchannel was also calculated. Beyond that, the combined effect of curve channel and wall properties on flow resistance was analyzed. This paper finds that wall properties have great influence on gas–liquid flow in microchannels not only on flow regime but also flow characteristics. Meanwhile, the pressure drop in curve microchannels is larger than straight. It is more beneficial for fluid flowing when the straight part of microchannel is hydrophilic smooth wall and curve part is hydrophobic with large roughness. Gas-liquid flow in serpentine microchannel with different surface properties exhibits drastically different flow behavior. With water and air as working fluids, the method of numerical simulation was adopted in this paper based on CLSVOF（coupled level set and volume of fluid method） multiphase model. After verifying the reasonability of the model through experiment, by changing wall properties and Re number（Re〈1500）, the influences of contact angle and surface roughness on flow regime and Po number were discussed. Moreover, the difference of pressure drop between curve and straight microchannel was also calculated. Beyond that, the combined effect of curve channel and wall properties on flow resistance was analyzed. This paper finds that wall properties have great influence on gas-liquid flow in microchannels not only on flow regime but also flow characteristics. Meanwhile, the pressure drop in curve microchannels is larger than straight. It is more beneficial for fluid flowing when the straight part of microchannel is hydrophilic smooth wall and curve part is hydrophobic with large roughness.

作者 Yunlong Zhou He Chang Tianyu Qi

机构地区 Energy and Power Engineering College Institute of Energy

出处《Chinese Journal of Chemical Engineering》 SCIE EI CAS CSCD 2017年第7期874-881,共8页 中国化学工程学报（英文版）

关键词 Serpentine microchannel Computational fluid dynamics Gas-liquid flow MICROFLUIDICS 气液两相流动微通道蛇纹石壁面润湿性多相流模型表面粗糙度流动特性

分类号 TQ021.1 [化学工程]

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参考文献1

1胡广,胡刚义,彭学创,唐滢,吕祥奎.粗糙度对微通道流动特性影响研究[J].舰船电子工程,2015,35(8):57-60. 被引量：4

二级参考文献11

1杨世铭.传热学[M].北京:高等教育出版社,2005. 被引量：23
2张田田.微通道内气体流动换热的理论与实验研究[D].北京:北京交通大学,2010 : 6-8. 被引量：2
3Ji Y, Yuan K, Chung J N. Numerical simulation of wall roughness on gaseous flow and heat transfer in a microchannel[J]. Heat Mass Transfer, 2006 (49): 1329-1339. 被引量：1
4Khadem M H, Shams M, Hossainpour S. Numerical simulation of roughness effects on flow and heat trans- fer in microchannels [J]. Heat Mass Transfer, 2009 (36):69-77. 被引量：1
5Choi S B, Barron R F, Warrington R O. Fluid flow and heat transfer in microtubes[J]. ASME DSC-32,1991: 123-134. 被引量：1
6Kohl M J, Abdel Khalik S I, Jeter S M, et al. An ex- perimental investigation of micro-channel flow with in- ternal pressure measurements [J]. Heat and Mass Transfer, 2005 (48) : 1518-1533. 被引量：1
7Wu P Y, Little W A. Measurement of the heat transfer characteristics of gas flow in fine channel heat exchang ers used for microminiature refrigerators[J]. Cryogen- ics, 1984:(24) : 415-420. 被引量：1
8Valses R, Miana J, Pelegay L, et al. Numerical inves- tigation of the influence of roughness on the laminar in- compressible fluid flow through annular microchannels [J]. Heat Mass Transfer,2007(50):1865-1878. 被引量：1
9Kandlikar S G, Joshi S, Tian S. Effect of channel roughness on heat transfer and fluid flow characteristics at low Reynolds numbers in small diameter tubes[C]// Proceedings of NHTC_01 35th National Heat Transfer Conference, Anaheim, CA,2001:1- 10. 被引量：1
10Mala G M, Li D. Flow characteristics of water in mi- crotubes[J]. Heat Mass Transfer, 1999(20) : 142-148. 被引量：1

共引文献3

1颜利波.人工粗糙元通道的流动与换热特性研究[J].经济视野,2016,0(15):157-157.
2周云龙,常赫.壁面性质对蛇形微通道流动特性的影响[J].原子能科学技术,2017,51(1):27-32. 被引量：4
3周云龙,常赫.入口角度及壁面性质对蛇形微通道内弹状流流动特性影响的格子Boltzmann模拟[J].高校化学工程学报,2017,31(2):323-328. 被引量：3

同被引文献57

1Yan Cao,Jun Li,Yang Jin,Jianhong Luo,Yubin Wang.Liquid–liquid two-phase mass transfer characteristics in a rotating helical microchannel[J].Chinese Journal of Chemical Engineering,2019,27(12):2937-2947. 被引量：4
2张忠培,董美蓉,冯哲愚,李晓静,陆继东.喷淋散射塔鼓泡区域的气液两相流动特性[J].当代化工,2020,0(3):539-543. 被引量：3
3刘赵淼,刘佳,申峰.不同重力下90°弯管内气液两相流流型及流动特性研究[J].力学学报,2015,47(2):223-230. 被引量：8
4张海峰,衣宝廉,侯明,张华民.流场尺寸对质子交换膜燃料电池性能的影响[J].电源技术,2004,28(8):494-497. 被引量：22
5张同旺,王金福,金涌.气液外环流反应器中气泡行为的实验研究[J].过程工程学报,2005,5(3):246-250. 被引量：3
6宋静.微通道内气-液两相流动特性研究[J].青岛科技大学学报（自然科学版）,2006,27(4):299-303. 被引量：8
7邹江,彭晓峰,颜维谋.壁面粗糙度对通道流动特性的影响[J].化工学报,2008,59(1):25-31. 被引量：26
8陈光文,乐军,袁权.Gas-Liquid Microreaction Technology： Recent Developments and Future Challenges[J].Chinese Journal of Chemical Engineering,2008,16(5):663-669. 被引量：18
9M.A. van der Hoef,J.A.M. Kuipers.Two-fluid modeling of Geldart A particles in gas-fluidized beds[J].Particuology,2008,6(6):540-548. 被引量：17
10袁希钢,宋文琦.T型结构微通道气液两相流型的数值模拟[J].天津大学学报,2012,45(9):763-769. 被引量：13

引证文献8

1周云龙,常赫.滑移壁面蛇形微通道两相流数值模拟[J].化工学报,2018,69(10):4194-4199.
2周云龙,常赫.非线性振动下水平通道内气液两相流动研究[J].原子能科学技术,2019,53(6):1014-1020. 被引量：2
3薄宇轩,吴晅,马骏,魏楠,刘鹏.气泡在静水中上升行为特性可视化实验研究[J].水动力学研究与进展（A辑）,2020,35(6):743-749. 被引量：3
4廖珮懿,杨代军,明平文,薛明喆,李冰,张存满.微流道气-液两相流研究及其在PEMFC中的应用进展[J].化工进展,2021,40(9):4734-4748. 被引量：1
5Weixi Guo,Chunying Zhu,Taotao Fu,Youguang Ma.Coalescence dynamics of two droplets of different viscosities in T-junction microchannel with a funnel-typed expansion chamber[J].Chinese Journal of Chemical Engineering,2021,34(10):43-52. 被引量：1
6王宜飞,王清强,姬德生,李申芳,金楠,赵玉潮.微通道壁面浸润性对气-液两相流的影响规律研究[J].化工学报,2022,73(4):1501-1514. 被引量：3
7Xuancheng Liu,Hongye Li,Yibing Song,Nan Jin,Qingqiang Wang,Xunli Zhang,Yuchao Zhao.Effects of channel wall wettability on gas-liquid dynamics mass transfer under Taylor flow in a serpentine microchannel[J].Chinese Journal of Chemical Engineering,2023,62(10):192-201. 被引量：1
8霍元浩,杨刚,张会臣.障碍微通道内气液两相流运动特性[J].过程工程学报,2023,23(12):1617-1626.

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2Li Ma,Yongjin Cui,Lin Sheng,Chencan Du,Jian Deng,Guangsheng Luo.Determination of interfacial tension and viscosity under dripping flow in a step T-junction microdevice[J].Chinese Journal of Chemical Engineering,2022,35(2):210-218.
3项星宇,王忠东,董艳鹏,李守川,朱春英,马友光,付涛涛.微通道内屈服应力型流体的流变特性及多相流研究进展[J].化工学报,2023,74(2):546-558. 被引量：1
4何万媛,陈一宇,朱春英,付涛涛,高习群,马友光.阵列凸起微通道内气液两相传质特性研究[J].化工学报,2023,74(2):690-697. 被引量：2
5宿恒,瞿叶高,彭志科.大变形柔性管道两相流流致振动研究[J].动力学与控制学报,2023,21(6):31-38.
6汤志轩,郭文华,吴思远,赵日晶,黄东.微通道蒸发器优化两相制冷剂分配及沸腾传热研究进展[J].化工学报,2023,74(10):4020-4036.
7袁谅,从海峰,李鑫钢.微通道内气液流动与传质特性的研究进展[J].化工进展,2024,43(1):34-48.
8马晓旭,刘太成,刘帅,田茂诚.管内气液两相流诱导振动研究进展[J].制冷技术,2023,43(6):76-82.
9李凤久,叶杨海,贾清梅,赵留成,柴思杨,杨钰,黄文露.磁化处理浮选药剂对气泡运动行为的影响研究[J].有色金属（选矿部分）,2024(6):32-39.
10韩龙喜,蒋安祺,王晨芳,牛祥明,赵金菁.水环境中油滴上浮运动特性实验研究[J].环境工程,2024,42(6):1-8.

1Xing Wang,Jiao Sun,Jie Zhao,Wenyi Chen.Experimental detection of bubble-wall interactions in a vertical gas–liquid flow[J].Chinese Journal of Chemical Engineering,2017,25(7):838-847. 被引量：5
2Xian-Bao Chen,Feng Gao.Energy Expenditure of Trotting Gait Under Different Gait Parameters[J].Chinese Journal of Mechanical Engineering,2017,30(4):943-950. 被引量：3
3孙开文,梁忠诚,赵瑞,孔梅梅,吴雯婷,张曼.微流控低通二阶滤波器的特性研究[J].电子元件与材料,2017,36(8):80-83.
4蔡建超,姚军,许友生.序言[J].地球科学（中国地质大学学报）,2017,42(8).

Chinese Journal of Chemical Engineering

2017年第7期

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