On the influence of droplet size on the breakup induction period in the flow behind a shock wave

A. A. Shebeleva^a, A. V. Minakov^ab, S. V. Poplavski^c, V. M. Boyko<sup>c

a</sup> 1Siberian Federal University, Krasnoyarsk, 660041 Russia
^b Kutateladze Institute of Thermophysics, Siberian Branch, Russian Academy of Sciences, Novosibirsk, 630090 Russia
^c Khristianovich Institute of Theoretical and Applied Mechanics, Siberian Branch, Russian Academy of Sciences, Novosibirsk, 630090 Russia

Abstract: In this paper, we computationally study the influence of the initial diameter of a water droplet on the dynamics and breakup induction period in the flow behind a passing shock wave. For this purpose, a series of calculations were performed for a fixed Weber number $\text{We} = 400$ and a variable initial diameter $d = 1.4, 2.8, 5.6$ mm of the water droplet. The numerical technique is based on the VOF method, the LES model is used to take into account turbulence, and the technology of adapted dynamic grids is used to describe the behavior of the interfacial boundary at main turbulent scales; this has made it possible to resolve secondary water droplets up to 20 $\mu$m in size. The droplet shape, the flow structure near and in the droplet wake, and the nature of mass entrainment were investigated. As a result of the calculations, the dependences of the breakup time on the dimensionless droplet diameter were obtained, the breakup induction time was determined, and the time constant of droplet interaction with the flow was calculated to estimate the droplet breakup lag.

Keywords: mathematical modeling, VOF method, LES model, dynamic grid, shock wave, aerodynamic droplet breakup, breakup induction time.

UDC: 533.6.011

Received: 04.08.2023
Revised: 11.03.2024
Accepted: 17.04.2024

DOI: 10.33048/SIBJIM.2024.27.312

 English version: Journal of Applied and Industrial Mathematics, 2024, 18:3, 548–557