TY - CONF
T1 - Numerical simulation and modeling of droplet spreading under smaller Weber numbers
AU - Wang, Ning
AU - Zhao, Changlu
AU - Zhang, Zhenyu
N1 - Publisher Copyright:
© 2021 ICLASS 2021 - 15th Triennial International Conference on Liquid Atomization and Spray Systems. All Rights Reserved.
PY - 2021/8/31
Y1 - 2021/8/31
N2 - Dynamic of droplet spreading on the free-slip surface was studied numerically by using the Front tracking method (FTM), with particularly interesting in the impacting under relatively small droplet inertias (We ≤ 30). Our predictions of dimensionless droplet maximum spreading diameter βmax agree well with the widely-used Wildeman et al.’s [J. Fluid Mech. 805: 636-655 (2016)] model at We>30. The “1/2 rule” (i.e., approximately one half of the initial kinetic energy finally transfer into surface energy) was found to break down at small Weber numbers (We ≤ 30) and droplet height is non-negligible when the energy conservation approach is employed to estimate βmax. Droplet spreading can be divided into three distinct regimes according to the deformation styles, namely, the puddle-shaped regime (I), the transition regime (II) and the pizza-shaped regime (III). Surface energy dominates the energy budget in regime (I), while kinetic energy dominates the energy budget in regime (III). A practical model for estimating β _max under small Weber numbers (We≤30) was proposed by accounting for the influence of impact parameters on the energy budget and the droplet height. Good agreement was found between our model and previous experiments.
AB - Dynamic of droplet spreading on the free-slip surface was studied numerically by using the Front tracking method (FTM), with particularly interesting in the impacting under relatively small droplet inertias (We ≤ 30). Our predictions of dimensionless droplet maximum spreading diameter βmax agree well with the widely-used Wildeman et al.’s [J. Fluid Mech. 805: 636-655 (2016)] model at We>30. The “1/2 rule” (i.e., approximately one half of the initial kinetic energy finally transfer into surface energy) was found to break down at small Weber numbers (We ≤ 30) and droplet height is non-negligible when the energy conservation approach is employed to estimate βmax. Droplet spreading can be divided into three distinct regimes according to the deformation styles, namely, the puddle-shaped regime (I), the transition regime (II) and the pizza-shaped regime (III). Surface energy dominates the energy budget in regime (I), while kinetic energy dominates the energy budget in regime (III). A practical model for estimating β _max under small Weber numbers (We≤30) was proposed by accounting for the influence of impact parameters on the energy budget and the droplet height. Good agreement was found between our model and previous experiments.
KW - Droplet spreading
KW - Maximum spreading diameter
KW - Modeling
KW - Small Weber numbers
UR - http://www.scopus.com/inward/record.url?scp=85180806230&partnerID=8YFLogxK
M3 - Paper
AN - SCOPUS:85180806230
T2 - 15th Triennial International Conference on Liquid Atomization and Spray Systems, ICLASS 2021
Y2 - 29 August 2021 through 2 September 2021
ER -
