Dynamic Wetting Behavior During Droplet Impacting on a Superheated Surface

Mingjing Chen, D. Chen, Hanzhou Liu
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Abstract

During the reflooding process after a loss-of-coolant-accident (LOCA) scenario, the highly superheated fuel surface of the reactor core will undergo a quenching process. The temperature of the fuel element surface drops sharply during the quenching process, because large droplets can pass through the vapor film to re-wet the wall surface, and the boiling mechanism is transformed from film boiling to nucleate boiling, the boiling heat transfer perfomance is greatly improved. But the transition of the boiling mechanism is closely related to the initial velocity of the droplet, the size of the droplet, and the wall temperature. At the same time, after the droplets hit the wall surface, dynamic wetting behaviors such as deposition, vibration, rebound, or splashing will occur. Unfortunatly, the mechanism of droplet wetting behavior on boiling heat transfer is not clear, so it is necessary to carry out a fundamental research. In this study, the droplet size, initial droplet velocity, substrate’s temperature and surface tilt angle were precisely controlled. The images were captured by a high-speed camera to obtain a dynamic wetting image of the droplets impacting the wall from room temperature to 400°C. Finally, based on the image analysis method, a simple analysis of the three-phase contact line movement and the droplet dynamic wetting behavoir is performed.
液滴撞击过热表面时的动态润湿行为
在失冷剂事故(LOCA)后的再注过程中,反应堆堆芯高度过热的燃料表面将经历一个淬火过程。在淬火过程中,燃料元件表面温度急剧下降,因为大液滴可以通过汽膜重新润湿壁面,沸腾机理由膜沸腾转变为成核沸腾,沸腾传热性能大大提高。但沸腾机理的转变与液滴的初始速度、液滴的大小和壁面温度密切相关。同时,液滴撞击壁面后,会发生沉积、振动、回弹或飞溅等动态润湿行为。然而,液滴润湿行为对沸腾换热的机理尚不清楚,因此有必要进行基础研究。在本研究中,对液滴尺寸、初始液滴速度、衬底温度和表面倾角进行了精确控制。图像由高速摄像机捕获,以获得从室温到400°C的液滴撞击壁面的动态润湿图像。最后,基于图像分析方法,对三相接触线运动和液滴动态润湿行为进行了简单分析。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
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