液滴对液体薄膜冲击后气泡封装的研究

IF 3.6 2区 工程技术 Q1 MECHANICS International Journal of Multiphase Flow Pub Date : 2023-07-01 DOI:10.1016/j.ijmultiphaseflow.2023.104450
Daniela F.S. Ribeiro , Miguel R.O. Panão , Jorge M.M. Barata , André R.R. Silva
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引用次数: 2

摘要

准确理解液滴撞击干/湿和冷/热表面的现象,对于在民用航空中实施生物燃料越来越重要。液滴撞击的结果取决于撞击前的条件,而当这种撞击发生在薄的液体薄膜上时,气泡的封装是一个很少研究的事件。因此,本文报道的实验工作的目的是研究这种气泡封装的机制。结果表明,气泡形成的机理分为两个阶段。在第一阶段,水滴撞击稳定的液膜后,立即发生飞溅,接着是冠状飞溅。相对于液膜,上升薄片以几乎正常的方向传播,但它在底部的半径继续扩大,最终导致包裹穹顶内空气的冠状边界向内坍塌。在第二阶段,会出现三种不同的气泡封装现象。在闭合冠的顶部,形成一个射流(现象1)或两个射流(现象2和3)。对于现象2,向上的射流最终由于引力影响而坍塌,而向下的射流继续增长,直到到达液膜,附着在液膜上,拉伸并从半球薄板顶部分离,形成气泡。在现象学3中,向上的射流高度足以使其在向上的射流崩溃之前破裂并喷射出一个大液滴。许多二次液滴落在气泡上,其中一个液滴最终会打破圆顶,导致更多的二次雾化。此外,研究了液滴撞击对液膜的第一次扰动,并提出了液滴传播速度的经验关系式。最后,对气泡几何进行了研究。
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Insights on bubble encapsulation after drop impact on thin liquid films

The accurate understanding of the phenomenology of drop impact onto dry/ wetted and cold/heated surfaces is increasingly relevant to implement biofuels in civil aviation. The outcome of drop impact depends on the pre-impact conditions and a seldom researched event is the encapsulation of a bubble when this impact occurs on thin liquid films. Therefore, the goal of the experimental work reported is to investigate the mechanism of this bubble encapsulation. Results show that the mechanism leading to a bubble formation has two stages. In the first stage, after the drop impacts a steady liquid film, a prompt splash occurs followed by a crown splash. The uprising sheet propagates in an almost normal direction relative to the liquid film, but its radius at the base continues to expand, eventually leading to the inward collapse of the crown-bounding rim encapsulating air inside the dome. In the second stage, three different phenomenologies of bubble encapsulation can occur. At the top of the closed crown, one jet (phenomenology 1) or two jets are formed (phenomenologies 2 and 3). For phenomenology 2, the upward jet eventually collapses due to gravitational influence, while the downward jet continues to grow until it reaches the liquid film, attaching to it, stretching and detaching from the top at the hemispheric thin sheet, forming a bubble. In phenomenology 3, the upward jet is high enough to allow its breakup and ejection of one large droplet before the collapse of the upward jet. Many secondary droplets fall on the bubble and one of them will eventually break the dome, leading to more secondary atomization. Additionally, the first perturbation imposed on the liquid film by the droplet impact is studied and an empirical correlation is proposed for its propagation velocity. Finally, bubble geometry is investigated.

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来源期刊
CiteScore
7.30
自引率
10.50%
发文量
244
审稿时长
4 months
期刊介绍: The International Journal of Multiphase Flow publishes analytical, numerical and experimental articles of lasting interest. The scope of the journal includes all aspects of mass, momentum and energy exchange phenomena among different phases such as occur in disperse flows, gas–liquid and liquid–liquid flows, flows in porous media, boiling, granular flows and others. The journal publishes full papers, brief communications and conference announcements.
期刊最新文献
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