滴状冷凝过程液滴自由表面温度场分析

兰忠; 朱霞; 彭本利; 林勐; 马学虎

doi:10.7498/aps.61.150508

摘要

对于滴状冷凝过程及其传热强化机理, 一般通过分析冷凝壁面上液滴分布和运动规律进行研究, 并且将单个液滴视为稳定的个体, 很少涉及液滴内部运动特征. 本文通过红外热像仪观测了纯蒸气滴状冷凝过程中, 液滴运动时自由表面温度场的演化过程. 发现在疏水壁面上, 液滴由于合并或脱落而发生移动过程中, 其自由表面温度先降低, 而后升高并高于移动前温度. 通过分析疏水表面上液滴移动过程的物理模型, 认为液滴移动时表面液膜发生履带式滚动现象, 或者发生液滴内部与自由表面附近的液体间形成对流和掺混现象. 对液滴运动时表面温度演变规律的分析表明: 触发液滴表面发生持续冷凝可能需要克服一个临界过冷度, 当气液间温差超过该临界值时才诱发冷凝; 液滴合并或脱落等整体运动过程, 导致了液滴内部的运动特征, 并促进了较大尺寸液滴表面发生直接冷凝, 这为强化冷凝传热的研究提供新的思路.

关键词:

Abstract

The invistigations on dropwise condensation process and the mechanism of heat transfer enhancement are usually based on the droplet distribution and the movement principle of droplets on condensing surface. In the meanwhile, a single droplet is treated as a stable individual and the movement property inside the droplet is rarely considered. With infrared thermography, the surface temperature distribution of condensate droplet during steam dropwise condensation process is observed. The result shows that the temperature of droplet surface first decreases and then increases and up to a value higher than the initial one as the droplet migrates from one position to another. The droplet will roll and the surface film would be tracked when the droplet moves on the hydrophobic surface. With the convection inside the droplet, condensate near the wall moves to the surface side. The analysis of surface temperature evolution of droplet indicates that the continuous condensation on droplet surface may occur when the surface subcooling exceeds a critical value. The direct condensation on large droplet surface can be promoted by the dynamic process such as droplet coalescence or falling off, which provides a new approach to the condensation heat transfer enhancement.

Keywords:

作者及机构信息

1.
大连理工大学化学工程研究所, 大连 116024

基金项目: 国家自然科学基金(批准号: 50906006)资助的课题.

Authors and contacts

1.
Institute of Chemical Engineering, Dalian University of Technology, Dalian 116024, China

Funds: Project supported by the National Natural Science Foundation of China (Grant No.50906006).

参考文献

[1]	Rose J W, Glicksman L R 1973 International Journal of Heat Mass Transfer 6 411
[2]	Gose E E, Mucciardi A N, Baer E 1967 International Journal of Heat Mass Transfer 10 15
[3]	Tanasawa I, Tachibana F, Ochiai 1978 Sixth International Heat Transfer Conference, Toronto,Ont., Canada, August 7-11 1978 p393
[4]	Cao Z J, Guo Y 1999 Acta Phys. Sin. 48 1823 (in Chinese) [曹治觉, 郭愚 1999 物理学报 48 1823]
[5]	Cao Z J 2002 Acta Phys. Sin. 51 25 (in Chinese) [曹治觉 2002 物理学报 51 25]
[6]	Zhu R C, Yan H, Wang X S 2010 Acta Phys. Sin. 59 7271 (in Chinese) [朱如曾, 闫红, 王小松 2010 物理学报 59 7271]
[7]	Fujiwara H, Kondo M 2005 Applied Physics Letters 86 032112
[8]	Klassen M, Dimarzo M, Sirkis J 1992 Experimental Thermal and Fluid Science 5 136
[9]	Barozzi G S, Corticelli M A, MacIver, T R, Tartarini, P 1999 Heat and Technology 17 13
[10]	Tartarini P, Corticelli M A, Tarozzi L 2009 Applied Thermal Engineering 29 1391
[11]	Ganzevles F L A , van der Geld C W M 2002 Int. J. Heat Mass Transfer 45 3233
[12]	Ganzevles F L A, van der Geld C W M 2004 Experimental Thermal and Fluid Science 28 237
[13]	Kim H, Buongiorno J 2011 International Journal of Multiphase Flow 37 166
[14]	Lan Z, Ma X H, Wang S F, Wang M Z, Li X N 2010 Chemical Engineering Journal 156 546
[15]	Qian B T, Shen Z Q 2006 Journal of Inorganic Materials 21 747
[16]	Rose J W 1981 Int. J. Heat Mass Transfer 24 191
[17]	Zhou X D 2007 Ph. D. Dissertation (dalian: Dalian University of Technology) (in Chinese) [周兴东 2007 博士学位论文 (大连: 大连理工大学)]
[18]	Wu W H, Maa J R 1976 The Chemical Engineering Journal 11 143

施引文献

[1]	Rose J W, Glicksman L R 1973 International Journal of Heat Mass Transfer 6 411
[2]	Gose E E, Mucciardi A N, Baer E 1967 International Journal of Heat Mass Transfer 10 15
[3]	Tanasawa I, Tachibana F, Ochiai 1978 Sixth International Heat Transfer Conference, Toronto,Ont., Canada, August 7-11 1978 p393
[4]	Cao Z J, Guo Y 1999 Acta Phys. Sin. 48 1823 (in Chinese) [曹治觉, 郭愚 1999 物理学报 48 1823]
[5]	Cao Z J 2002 Acta Phys. Sin. 51 25 (in Chinese) [曹治觉 2002 物理学报 51 25]
[6]	Zhu R C, Yan H, Wang X S 2010 Acta Phys. Sin. 59 7271 (in Chinese) [朱如曾, 闫红, 王小松 2010 物理学报 59 7271]
[7]	Fujiwara H, Kondo M 2005 Applied Physics Letters 86 032112
[8]	Klassen M, Dimarzo M, Sirkis J 1992 Experimental Thermal and Fluid Science 5 136
[9]	Barozzi G S, Corticelli M A, MacIver, T R, Tartarini, P 1999 Heat and Technology 17 13
[10]	Tartarini P, Corticelli M A, Tarozzi L 2009 Applied Thermal Engineering 29 1391
[11]	Ganzevles F L A , van der Geld C W M 2002 Int. J. Heat Mass Transfer 45 3233
[12]	Ganzevles F L A, van der Geld C W M 2004 Experimental Thermal and Fluid Science 28 237
[13]	Kim H, Buongiorno J 2011 International Journal of Multiphase Flow 37 166
[14]	Lan Z, Ma X H, Wang S F, Wang M Z, Li X N 2010 Chemical Engineering Journal 156 546
[15]	Qian B T, Shen Z Q 2006 Journal of Inorganic Materials 21 747
[16]	Rose J W 1981 Int. J. Heat Mass Transfer 24 191
[17]	Zhou X D 2007 Ph. D. Dissertation (dalian: Dalian University of Technology) (in Chinese) [周兴东 2007 博士学位论文 (大连: 大连理工大学)]
[18]	Wu W H, Maa J R 1976 The Chemical Engineering Journal 11 143

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