Thin-liquid-film evaporation at contact line

被引:4
|
作者
Wang H. [1 ]
Pan Z. [1 ]
Chen Z. [1 ]
机构
[1] Department of Energy and Resources Engineering, College of Engineering, Peking University
来源
Frontiers of Energy and Power Engineering in China | 2009年 / 3卷 / 2期
基金
中国国家自然科学基金;
关键词
Contact line; Disjoining pressure; Evaporation; Meniscus; Thin film;
D O I
10.1007/s11708-009-0020-2
中图分类号
学科分类号
摘要
When a liquid wets a solid wall, the extended meniscus near the contact line may be divided into three regions: a nonevaporating region, where the liquid is adsorbed on the wall; a transition region or thin-film region, where effects of long-range molecular forces (disjoining pressure) are felt; and an intrinsic meniscus region, where capillary forces dominate. The thin liquid film, with thickness from nanometers up to micrometers, covering the transition region and part of intrinsic meniscus, is gaining interest due to its high heat transfer rates. In this paper, a review was made of the researches on thin-liquid-film evaporation. The major characteristics of thin film, thin-film modeling based on continuum theory, simulations based on molecular dynamics, and thin-film profile and temperature measurements were summarized. © 2009 Higher Education Press and Springer-Verlag GmbH.
引用
收藏
页码:141 / 151
页数:10
相关论文
共 50 条
  • [21] Numerical model for thin liquid film with evaporation and condensation on solid surfaces in systems with conjugated heat transfer
    Sosnowski, P.
    Petronio, A.
    Armenio, V.
    INTERNATIONAL JOURNAL OF HEAT AND MASS TRANSFER, 2013, 66 : 382 - 395
  • [22] Analysis of Evaporation Heat Transfer of Thin Liquid Film in a Capillary of Equilateral Triangular Cross-Section
    Miao JianyinWang JinliangMa Tongze Institute of Spacecraft System Engineering
    Journal of Thermal Science, 2001, (04) : 348 - 356
  • [23] Prediction of Thin Liquid Film Evaporation Characteristics with a Thermal Lattice Boltzmann Method
    Yang, Weilin
    Li, Hongxia
    Alhosani, Mohamed H.
    Zhang, TieJun
    2016 15TH IEEE INTERSOCIETY CONFERENCE ON THERMAL AND THERMOMECHANICAL PHENOMENA IN ELECTRONIC SYSTEMS (ITHERM), 2016, : 1240 - 1247
  • [24] Evaporation of a Thin Binary Liquid Film by Forced Convection into Air and Superheated Steam
    Nasr, Abdelaziz
    Debbissi, Chokri
    Ben Nasrallah, Sassi
    JOURNAL OF THERMAL SCIENCE, 2010, 19 (04) : 346 - 356
  • [25] Evaporation heat transfer of thin liquid film and meniscus in microcapillary and on substrate with nanorelief
    Qu, W
    Zhang, LC
    Ma, TZ
    Ge, XS
    JOURNAL OF ENHANCED HEAT TRANSFER, 2002, 9 (3-4) : 161 - 170
  • [26] Evaporation of a thin binary liquid film by forced convection into air and superheated steam
    Abdelaziz Nasr
    Chokri Debbissi
    Sassi Ben Nasrallah
    Journal of Thermal Science, 2010, 19 : 346 - 356
  • [27] Evaporation of a Thin Binary Liquid Film by Forced Convection into Air and Superheated Steam
    Abdelaziz Nasr
    Chokri Debbissi
    Sassi Ben Nasrallah
    JournalofThermalScience, 2010, 19 (04) : 346 - 356
  • [28] Determining the Heat Flux Density in the Area of a Contact Line during the Evaporation of Liquid into a Bubble
    Sibiryakov N.E.
    Kochkin D.Y.
    Kabov O.A.
    Karchevsky A.L.
    Journal of Applied and Industrial Mathematics, 2023, 17 (03) : 628 - 639
  • [29] Adsorption, evaporation, condensation, and fluid flow in the contact line region
    Wayner, PC
    CONTACT ANGLE, WETTABILITY AND ADHESION, VOL 3, 2003, : 3 - 23
  • [30] Liquid film dynamics with immobile contact line during meniscus oscillation
    Zhang, Xiaolong
    Nikolayev, Vadim S.
    JOURNAL OF FLUID MECHANICS, 2021, 923
12345