Experimental study on droplets boiling on micro-pillar structure surface with constant temperatures

doi:10.11949/0438-1157.20190362

Abstract

Abstract:

The high-speed imaging technique was used to observe the evaporation and nucleation process of the droplets of deionized water after impacting the surface of the micro-pillar structure. The results show that the evaporation time of droplet decreased with the increase of wall temperature. Compared with smooth surface, the heat transfer coefficient (HTC) of micro-pillar surface can be only enhanced under certain conditions. In this paper the temperature is 50, 60, 70, 80 and 120℃,and the strengthening effect is best at 120℃. The evaporation of droplet can be divided into two stages. In the first stage, the diameter of the droplets is constant, and the height changes. In the second stage, the thickness of the droplet is close to the height of micro-pillar structure and the droplet dry in a very short time. As the wall temperature increases, the period of the first stage decreases obviously, and the nucleation density and the bubble diameter increase accordingly. It is worth to note that nucleation bubbles show a radial distribution on the micro-pillar surface because of the structure of array micro-pillars and the impact of dropping down.

Key words: droplet impacting, micro-pillar structure, evaporation, nucleation site, bubble diameter, bubble distribution

摘要：

利用高速摄像技术对去离子水液滴撞击微柱结构表面后的蒸发及核化过程进行观测。实验测得不同壁面温度下液滴蒸干时间，获得液滴沸腾曲线；发现相对光滑表面，微柱表面在50、60、70、80、120℃强化相变换热，120℃时强化比例最大，达到35.71%；壁温为90、100、110℃时，微柱表面无强化作用。从液滴直径和厚度的变化可知微柱表面液滴蒸发分为两个阶段：第一阶段，液滴直径不变，厚度变化；第二阶段，液滴厚度接近微柱高度，直径减小。随壁温升高，第一阶段时长显著缩短。液滴内部核化点密度和气泡平均直径随壁面温度的升高均有明显增大的趋势。需指出的是，液滴冲击对微柱表面液滴内部核化点分布有重要影响，受微柱结构及滴落冲击作用液滴内部成核气泡沿液滴半径呈辐射状分布。

关键词: 液滴撞击, 微柱结构, 蒸发, 汽化核心, 气泡直径, 气泡分布

CLC Number:

TK 121

Hongxia CHEN, Hongyang XIAO, Yuan SUN, Lin LIU. Experimental study on droplets boiling on micro-pillar structure surface with constant temperatures[J]. CIESC Journal, 2019, 70(9): 3363-3369.

陈宏霞, 肖红洋, 孙源, 刘霖. 微柱表面液滴定壁温沸腾实验研究[J]. 化工学报, 2019, 70(9): 3363-3369.

Figures/Tables 9

References 31

1	Mao T , Kuhn D C S , Tran H . Spread and rebound of liquid droplets upon impact on flat surfaces[J]. AIChE Journal, 1997, 43(9): 2169-2179.
2	陆规, 彭晓峰, 王晓东 . 核化沸腾液滴的铺展实验观察[J]. 热科学与技术, 2006, 5(3): 195-200.
	Lu G , Peng X F , Wang X D . Experimental investigation on spreading of droplets with evaporation and nucleation[J]. Journal of Thermal Science and Technology, 2006, 5(3): 195-200.
3	Mehdi-Nejad V , Mostaghimi J , Chandra S . Air bubble entrapment under an impacting droplet[J]. Physics of Fluids, 2003, 15(1): 173-183.
4	Li X , Mao L , Ma X . Dynamic behavior of water droplet impact on microtextured surfaces: the effect of geometrical parameters on anisotropic wetting and the maximum spreading diameter[J]. Langmuir, 2013, 29(4): 1129-1138.
5	Li X , Ma X , Lan Z . Dynamic behavior of the water droplet impact on a textured hydrophobic/superhydrophobic surface: the effect of the remaining liquid film arising on the pillars’ tops on the contact time[J]. Langmuir, 2010, 26(7): 4831-4838.
6	Kannan R , Sivakumar D . Drop impact process on a hydrophobic grooved surface[J]. Colloids and Surfaces A: Physicochemical and Engineering Aspects, 2008, 317(1/2/3): 694-704.
7	施其明, 贾志海, 林琪焱 . 液滴撞击微结构疏水表面的动态特性[J]. 化工进展, 2016, 35(12): 3818-3824.
	Shi Q M , Jia Z H , Lin Q Y . Dynamic behavior of droplets impacting on microstructured hydrophobic surfaces[J]. Chemical Industry and Engineering Progress, 2016, 35(12): 3818-3824.
8	Nakoryakov V E , Misyura S Y , Elistratov S L . The behavior of water droplets on the heated surface[J]. International Journal of Heat and Mass Transfer, 2012, 55(23/24): 6609-6617.
9	王晓东, 陆规, 彭晓峰, 等 . 加热板上蒸发液滴动态特性的实验[J]. 航空动力学报, 2006, 21(6): 1001-1007.
	Wang X D , Lu G , Peng X F , et al . Experimental investigation of dynamic evaporation characteristics of liquid droplet on heated surface[J]. Journal of Aerospace Power, 2006, 21(6): 1001-1007.
10	陆规, 彭晓峰, 冯妍卉 . 加热板上液滴沸腾实验研究[J]. 热科学与技术, 2009, 8(3): 198-204.
	Lu G , Peng X F . Feng Y H. Experimental investigation of boiling of droplets on heated surfaces[J]. Journal of Thermal Science and Technology, 2009, 8(3): 198-204.
11	梁刚涛, 牟兴森, 郭亚丽, 等 . 液滴冲击加热壁面沸腾现象特征分析[J]. 化工学报, 2016, 67(6): 2211-2217.
	Liang G T , Mu X S , Guo Y L , et al . Characteristic analyses of boiling phenomena in process of drops impingement on heated surfaces[J]. CIESC Journal, 2016, 67(6): 2211-2217.
12	Liang G , Shen S , Guo Y , et al . Boiling from liquid drops impact on a heated wall[J]. International Journal of Heat and Mass Transfer, 2016, 100: 48-57.
13	Tran T , Staat H J J , Susarrey-Arce A , et al . Droplet impact on superheated micro-structured surfaces[J]. Soft Matter, 2013, 9(12): 3272-3282.
14	Hays R , Maynes D , Crockett J . Thermal transport to droplets on heated superhydrophobic substrates[J]. International Journal of Heat and Mass Transfer, 2016, 98: 70-80.
15	Duursma G , Kennedy R , Sefiane K , et al . Leidenfrost droplets on microstructured surfaces[J]. Heat Transfer Engineering, 2016, 37(13/14): 1190-1200.
16	Kwon H , Bird J C , Varanasi K K . Increasing Leidenfrost point using micro-nano hierarchical surface structures[J]. Applied Physics Letters, 2013, 103(20): 201601.
17	Misyura S Y . The effect of Weber number, droplet sizes and wall roughness on crisis of droplet boiling[J]. Experimental Thermal and Fluid Science, 2017, 84: 190-198.
18	Tartarini P , Lorenzini G , Randi M R . Experimental study of water droplet boiling on hot, non-porous surfaces[J]. Heat and Mass Transfer, 1999, 34(6): 437-447.
19	沈胜强, 张洁珊, 梁刚涛 . 液滴撞击加热壁面传热实验研究[J]. 物理学报 2015, 64(13): 134704.
	Shen S Q , Zhang J S , Liang G T . Experimental study of heat transfer from droplet impact on a heated surface[J]. Acta Physica Sinica, 2015, 64(13): 134704.
20	Wu Y , Zhang X , Zhang X , et al . Modeling and experimental study of vapor phase-diffusion driven sessile drop evaporation[J]. Applied Thermal Engineering, 2014, 70(1): 560-564.
21	Misyura S Y . Contact angle and droplet heat transfer during evaporation on structured and smooth surfaces of heated wall[J]. Applied Surface Science, 2017, 414: 188-196.
22	Misyura S Y . Wall effect on heat transfer crisis[J]. Experimental Thermal and Fluid Science, 2016, 70: 389-396.
23	Misyura S Y . Nucleate boiling in bidistillate droplets[J]. International Journal of Heat and Mass Transfer, 2014, 71: 197-205.
24	Misyura S Y . Droplets boiling crisis of ethanol water solution on duralumin substrate with SiO₂ nanoparticles coating[J]. Experimental Thermal and Fluid Science, 2016, 75: 43-53.
25	Song D , Song B , Hu H , et al . Contact angle and impinging process of droplets on partially grooved hydrophobic surfaces[J]. Applied Thermal Engineering, 2015, 85: 356-364.
26	Mollaret R , Sefiane K , Christy J R E , et al . Experimental and numerical investigation of the evaporation into air of a drop on a heated surface[J]. Chemical Engineering Research and Design, 2004, 82(4): 471-480.
27	Deendarlianto, Takata Y , Hidaka S , et al . Effect of static contact angle on the droplet dynamics during the evaporation of a water droplet on the hot walls[J]. International Journal of Heat and Mass Transfer, 2014, 71: 691-705.
28	宋云超, 宁智, 孙春华, 等 . 液滴撞击壁面气泡的产生及运动研究[J]. 机械工程学报, 2014, 50(2): 153-158.
	Song Y C , Ning Z , Sun C H , et al . Research on the generation and movement of the bubble inside impacting droplet[J]. Journal of Mechanical Engineering, 2014, 50(2): 153-158.
29	Chaves H , Kubitzek A M , Obermeier F . Dynamic processes occurring during the spreading of thin liquid films produced by drop impact on hot walls[J]. International Journal of Heat and Fluid Flow, 1999, 20(5): 470-476.
30	Nikolopoulos N , Theodorakakos A , Bergeles G . A numerical investigation of the evaporation process of a liquid droplet impinging onto a hot substrate[J]. International Journal of Heat and Mass Transfer, 2007, 50(1/2): 303-319.
31	Lu G , Wang X D , Yan W M . Nucleate boiling inside small evaporating droplets: an experimental and numerical study[J]. International Journal of Heat and Mass Transfer, 2017, 108: 2253-2261.

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名称	型号规格	用途	误差
加热板	150 kW	加热单晶硅板
热电偶	K型	测量壁温，温控测温	0.2 K
可编程数显温控仪	XMTA-818P	控制壁面温度	1 K
液滴生成器	MD	生成液滴，并控制液滴体积	<1.5%
数据采集仪	Agilent34970A	测量壁面温度	＜0.1%
高速相机	千眼狼2F04	监测液滴侧面形态变化，最高6000帧	＜1ms
高速相机	Optronis CP80-4-M-500	观测液滴内部核化情况，最高23000帧	<0.25 ms
单晶硅板	30 mm×30 mm×0.6 mm	表面具有微柱结构

名称	型号规格	用途	误差
加热板	150 kW	加热单晶硅板
热电偶	K型	测量壁温，温控测温	0.2 K
可编程数显温控仪	XMTA-818P	控制壁面温度	1 K
液滴生成器	MD	生成液滴，并控制液滴体积	<1.5%
数据采集仪	Agilent34970A	测量壁面温度	＜0.1%
高速相机	千眼狼2F04	监测液滴侧面形态变化，最高6000帧	＜1ms
高速相机	Optronis CP80-4-M-500	观测液滴内部核化情况，最高23000帧	<0.25 ms
单晶硅板	30 mm×30 mm×0.6 mm	表面具有微柱结构