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液滴平壁铺展过程中的滞后效应及力学机制研究

焦云龙 刘小君 逄明华 刘焜

文章导航 > 应用数学和力学  > 2016 >  37(1): 14-26
焦云龙, 刘小君, 逄明华, 刘焜. 液滴平壁铺展过程中的滞后效应及力学机制研究[J]. 应用数学和力学, 2016, 37(1): 14-26. doi: 10.3879/j.issn.1000-0887.2016.01.002
引用本文: 焦云龙, 刘小君, 逄明华, 刘焜. 液滴平壁铺展过程中的滞后效应及力学机制研究[J]. 应用数学和力学, 2016, 37(1): 14-26. doi: 10.3879/j.issn.1000-0887.2016.01.002
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JIAO Yun-long, LIU Xiao-jun, PANG Ming-hua, LIU Kun. Study of Contact Angle Hysteresis at Moving Contact Lines Based on CFD Simulation and Mechanical Analysis[J]. Applied Mathematics and Mechanics, 2016, 37(1): 14-26. doi: 10.3879/j.issn.1000-0887.2016.01.002
Citation: JIAO Yun-long, LIU Xiao-jun, PANG Ming-hua, LIU Kun. Study of Contact Angle Hysteresis at Moving Contact Lines Based on CFD Simulation and Mechanical Analysis[J]. Applied Mathematics and Mechanics, 2016, 37(1): 14-26. doi: 10.3879/j.issn.1000-0887.2016.01.002
shu

液滴平壁铺展过程中的滞后效应及力学机制研究

doi: 10.3879/j.issn.1000-0887.2016.01.002

  • 合肥工业大学 摩擦学研究所, 合肥 230009

基金项目: 国家自然科学基金(51375132)
详细信息
    作者简介:

    焦云龙(1990—),男,博士生(E-mail: jiaoyunlong0823@126.com);刘焜(1963—),男,教授,博士生导师(通讯作者. E-mail: liukun@hfut.edu.cn).

  • 中图分类号: O359

Study of Contact Angle Hysteresis at Moving Contact Lines Based on CFD Simulation and Mechanical Analysis

  • Institute of Tribology, Hefei University of Technology, Hefei 230009, P.R.China

Funds: The National Natural Science Foundation of China(51375132)

    摘要
  • 摘要: 研究了液滴平壁铺展过程中的接触角滞后效应,从接触线附近流体的压力、速度以及能量分布等角度考虑滞后效应的成因和变化规律.在此基础之上分析了固体表面粗糙度对滞后效应的影响,并借助部分三维形貌参数(ISO 25178)建立了固体表面形貌与接触角滞后效应之间的量化关系.为了研究以上内容,应用数值仿真软件建立了液滴铺展动力学模型,并结合固体表面上的滞后性实验进行了相关验证.研究结果表明:由于表面粗糙度的存在,液滴铺展至平衡位置时,位于铺展前沿的液体分子被钉扎在固体表面的凹坑或低谷中,使得前沿接触角逐渐增大,后沿接触角逐渐减小,接触角发生滞后;驱动液滴铺展的Laplace压力和自身重力与阻碍液滴铺展的黏性阻力之间的平衡关系,是接触角发生滞后的主要力学机制.另外,实验结果表明接触角滞后效应与固体表面形貌密切相关,具有相同表面粗糙度(Sa)的固体表面,由于表面形貌不同接触角滞后效应可能存在明显的差异.
    Abstract: Contact angle hysteresis (CAH) is one of the significant phenomena in the process of droplet spreading on solid surfaces. It plays an important role in mechanical lubrication and other industrial applications. CAH on both smooth and rough surfaces was studied through parametric analysis based on numerical simulation and ISO 25178. The changes of kinetic energy of molecules, liquid pressure and flow velocity near the moving contact line (MCL) related to the mechanism of CAH were investigated with the Flow-3D software. In addition, quantitative tests of the relationship between surface roughness and CAH were conducted with several key parameters according to ISO 25178. The results show that the contact angle is not usually equal to the Young’s contact angle because of the influence of surface roughness; the dynamic balance between sliding force (caused by Laplace pressure and droplet gravity) and viscous resistance (caused by surface roughness) at the MCL is the main reason for the occurrence of CAH. Moreover, CAH is closely related to surface topography, the CAH results on various substrates with different micro-texture types show great differences. The present study enhances the understanding of the CAH mechanism from a micro-perspective and provides some guidance for the practical manufacture of surfaces with better lubrication property and wettability.
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    • 参考文献(19)
  • [1] 赵亚溥. 表面与界面物理力学[M]. 北京: 科学出版社, 2012: 381-385.(ZHAO Ya-pu. Physical Mechanics on the Surface and Interface [M]. Beijing: Science Press, 2012: 381-385.(in Chinese))
    [2] de Gennes P G. Wetting: statics and dynamics[J]. Reviews of Modern Physics,1985,57(3): 827-863.
    [3] 杨淑燕, 郭峰, 马冲. 固液润湿性对流体动压润滑薄膜的影响[J]. 摩擦学学报, 2010,30(2): 203-208.(YANG Shu-yan, GUO Feng, MA Chong. Influences of the liquid/solid wettability on thin hydrodynamic lubrication films[J]. Tribology,2010,30(2): 203-208.(in Chinese))
    [4] Andrade J D, Smith L M, Gregonis D E. The contact angle and interface energetics[C]//Andrade J D, ed. Surface and Interfacial Aspects of Biomedical Polymers. Vol1. New York, London: Plenum Press, 1985.
    [5] Rao D N. The concept, characterization, concerns and consequences of contact angles in solid-liquid-liquid systems[C]//Mittal K L, ed. Contact Angle, Wettability and Adhesion.Vol3. Utrecht: VSP, 2003: 191-210.
    [6] Wang B B, Zhao Y P, Yu T X. Fabrication of novel superhydrophobic surfaces and droplet bouncing behavior—part 2: water droplet impact experiment on superhydrophobic surfaces constructed using ZnO nanoparticles[J]. Journal of Adhesion Science and Technology,2011,25(1/3): 93-108.
    [7] 赵亚溥. 纳米与介观力学[M]. 北京: 科学出版社, 2014: 337-341.(ZHAO Ya-pu. Nano and Mesoscopic Mechanics [M]. Beijing: Science Press, 2014: 337-341.(in Chinese))
    [8] Nadkarni G D, Garoff S. An investigation of microscopic aspects of contact angle hysteresis: pinning of the contact line on a single defect[J].Europhysics Letters,1992,20: 523-528.
    [9] 秦亮, 刘天庆. 亲/疏水表面上液滴滞后阻力的研究[J]. 化工进展, 2012,31(8): 1711-1716.(QIN Liang, LIU Tian-qing. Investigation on the hysteretic force of droplet on hydrophilic and hydrophobic surface[J].Chemical Industry and Engineering Process,2012,31(8): 1711-1716.(in Chinese))
    [10] 王晓东, 彭晓峰, 闵敬春, 刘涛. 接触角滞后现象的理论分析[J]. 工程热物理学报, 2002,23(1): 67-70.(WANG Xiao-dong, PENG Xiao-feng, MING Jing-chun, LIU Tao. Hysteresis of contact angle at liquid-solid interface[J].Journal of Engineering Thermophysics,2002,23(1): 67-70.(in Chinese))
    [11] 王晓东, 彭晓峰, 陆建峰, 刘涛, 王补宣. 粗糙表面接触角滞后现象分析[J]. 热科学与技术, 2003,2(3): 230-234.(WANG Xiao-dong, PENG Xiao-feng, LU Jian-feng, LIU Tao, WANG Bu-xuan. Contact angle hysteresis on rough surface[J]. Journal of Thermal Science and Technology,2003,2(3): 230-234.(in Chinese))
    [12] 魏明锐, 刘明嘉, 颜伏伍, 刘元, 许伟康. 液滴平壁铺展过程分析[J]. 内燃机学报, 2012,30(6): 539-543.(WEI Ming-rui, LIU Ming-jia, YAN Fu-wu, LIU Yuan, XU Wei-kang. Analysis of spreading process of droplet on flat surface[J]. Transaction of CSICE,2012,30(6): 539-543.(in Chinese))
    [13] 曹晓平, 蒋亦民. 浸润接触线的摩擦性质与固体表面张力的Wenzel行为[J]. 物理学报, 2005,54(5): 2203-2205.(CAO Xiao-ping, JIANG Yi-ming. The frictional property of wetting line and Wenzel behavior of surface tension[J]. Acta Physica Sincia,2005,54(5): 2203-2205.(in Chinese))
    [14] WANG Feng-chao, ZHAO Ya-pu. Contact angle hysteresis at the nanoscale: a molecular dynamics simulation study[J].Colloid and Polymer Science,2013,291(2): 307-315.
    [15] Young T. An essay on the cohesion of fluids[J]. Philosophical Transactions of the Royal Society of London,1805,95: 65-87.
    [16] Adam N K, Jessop G. Angles of contact and polarity of solid surfaces[J]. Journal of the Chemical Society, Transactions,1925,127: 1863-1868.
    [17] Derjaguin B V. Definition of the concept of , and the magnitude of the disjoining pressure and its role in the statics and kinetics of thin layers liquids[J]. Kolloidnyi Zhurnal,1955,17: 191-197.
    [18] Wenzel R N. Resistance of solid surfaces to wetting by water[J]. Industrial and Engineering Chemistry,1936,28(8): 988-994.
    [19] Shanahan M E R, Carré A. Nanometric solid deformation of soft material in capillary phenomena[C]//Rosoff M, ed. Nano-Surface Chemistry.New York: Marcel Dekker, Inc, 2002.
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出版历程
  • 收稿日期:  2015-08-28
  • 修回日期:  2015-12-07
  • 刊出日期:  2016-01-16

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