双液滴正碰撞后的扩散、振动和断裂行为研究

IF 2.1 4区 工程技术
Jinjuan Sun, Zhiheng Ma, Jianhui Tian, Runling Peng
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引用次数: 0

摘要

液滴碰撞现象是一种较为复杂的传热传质相变现象,受动力学和热力学的共同作用。在碰撞过程中,双液滴的相互融合干扰使得液滴碰撞后的动力学机理更加复杂,对其深入研究可为工程应用、工业生产和湿壁设计等领域提供重要的理论支持。为了研究双液滴正碰撞后的动力学行为,本文主要结合实验和数值模拟方法,研究同体积双液滴碰撞后的扩散、振动和断裂特性。首先,将融合液滴和单液滴的反弹振动等效为单自由度阻尼振动系统,通过实验方法对比分析了单液滴和双液滴在相同碰撞速度下碰撞后的铺展和振动特性。结果表明,当液滴不发生断裂时,随着碰撞速度的增加,单液滴和双液滴的铺展系数和阻尼系数逐渐增大,振动时间逐渐减小。双液滴的阻尼系数和振动时间均高于单液滴,而扩展因子则低于单液滴。然后,深入研究了双液滴的正碰撞现象,发现熔融液滴的扩散因数随液滴直径、碰撞速度和壁面接触角的增大而增大。受低壁温的影响,熔融液滴发生相变,从而影响液滴底部的流动,导致阻尼系数增大,振动时间缩短。随着碰撞速度和壁面接触角的减小,阻尼系数逐渐增大,振动时间逐渐减小。最后,数值模拟方法揭示了双液滴正碰撞后会发生反弹断裂和扩展断裂现象,并找到了发生反弹断裂和扩展断裂所需的碰撞速度临界值。这为研究多液滴在壁面上碰撞后的传热传质过程提供了可靠的理论依据。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
Study of spreading, vibration, and fracture behavior of double droplets after positive collision
The droplet collision phenomenon is a more complex heat and mass transfer phase transition phenomenon, which is subject to the joint action of kinetics and thermodynamics. During the collision process, the mutual fusion interference of double droplets makes the kinetic mechanism after droplet collision more complicated, and its in-depth study can provide important theoretical support for the fields of engineering applications, industrial production and wetted wall design. In order to investigate the kinetic behavior of double droplets positive collision, this paper mainly combines experimental and numerical simulation methods to investigate the spreading, vibration and fracture characteristics of double droplets of the same volume after collision. Firstly, the rebound vibration of the fused droplet and single droplet is equivalent to a single-degree-of-freedom damped vibration system, and the spreading and vibration characteristics of the single droplet and the double droplets after collision under the same collision velocity are analyzed comparatively by experimental methods. The results show that when the droplet does not fracture, the spreading factor and damping coefficient of single droplet and double droplets gradually increase with the increase of collision velocity, and the vibration time gradually decreases. The damping coefficient and vibration time of the double droplets are higher than that of the single droplet, while the spreading factor is lower than that of the single droplet. Then, the double droplets positive collision phenomenon is studied in depth, and it is found that the spreading factor of the fused droplet increases with the increase of the droplet diameter, the collision velocity, and the wall contact angle. Affected by the low wall temperature, the fused droplet undergoes a phase transition, which affects the bottom flow of the droplet, leading to an increase in the damping coefficient and a decrease in the vibration time. With the decrease of the collision velocity and wall contact angle, the damping coefficient gradually increases and the vibration time decreases. Finally, the numerical simulation method reveals that rebound fracture and spreading fracture phenomena occur after double droplets positive collision, and the critical values of the collision velocity required for the occurrence of rebound fracture and spreading fracture are found. This provides a reliable theoretical basis for the study of the heat and mass transfer process after the collision of multiple droplets on the wall.
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来源期刊
Advances in Mechanical Engineering
Advances in Mechanical Engineering Engineering-Mechanical Engineering
自引率
4.80%
发文量
353
期刊介绍: Advances in Mechanical Engineering (AIME) is a JCR Ranked, peer-reviewed, open access journal which publishes a wide range of original research and review articles. The journal Editorial Board welcomes manuscripts in both fundamental and applied research areas, and encourages submissions which contribute novel and innovative insights to the field of mechanical engineering
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