1. Collision dynamics of binary equal-size droplets at high pressures: a focus on stretching separation and reflexive separation.
- Author
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Bu, Jingqi, Li, Longfei, Zhang, Fan, Zhong, Shenghui, Liao, Xifeng, Liu, Zhuoxin, Du, Qing, Fan, Linhao, and Jiao, Kui
- Subjects
ENERGY dissipation ,LIGAMENT injuries ,MICROSPACECRAFT ,KINETIC energy ,DEFORMATIONS (Mechanics) - Abstract
Stretching separation and reflexive separation are two collision regimes that give rise to satellite droplets, significantly impacting the droplet size distribution. However, the influence of high pressure on these regimes remains unclear. This paper investigates the collision dynamics of binary equal-size droplets under varying ambient pressures using the volume of fluid method and adaptive mesh refinement. The results show that vortices, generated during droplet motion changes or ligament ruptures, facilitate mass transport within the droplet–droplet deformation. Additionally, this paper summarizes four phases of droplet deformation in the separation regimes, which are delayed in stretching separation and advanced in reflexive separation with increasing ambient pressure. Elevated ambient pressure restricts droplet movement, resulting in tougher ligament fractures, smaller satellite droplets, and an expanded coalescence regime boundary. Unlike previous works, this paper incorporates gas kinetic and dissipation energies during droplet collisions at high pressures, revealing that at 7 MPa, the gas dissipation energy is comparable to the liquid dissipation energy and cannot be neglected. To account for these effects, a pressure-dependent formula is integrated into the composite collision model under the Lagrangian framework, offering enhanced predictions of droplet size within the stretching separation regime. [ABSTRACT FROM AUTHOR]
- Published
- 2024
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