TY - GEN
T1 - Influence of Scale Effects on the Dynamics of Water Entry Across the Air-Water Interface
AU - Yu, Yilan
AU - Shi, Yao
AU - Pan, Guang
AU - Huang, Qiaogao
N1 - Publisher Copyright:
© 2025 IEEE.
PY - 2025
Y1 - 2025
N2 - This study investigates the scale effects of structures with different scaling factors under identical water entry velocities based on a high-accuracy numerical simulation technique for flow fields. By comparing water entry velocity, cavity evolution characteristics, flow field parameters, and turbulence properties, the differences between scaled and full-scale models are analyzed. The results indicate that surface tension effects are enhanced in the scaled-down models, and different scaled models exhibit consistent dimensionless velocity at the same dimensionless time. The scaled-down models demonstrate higher local flow velocity, while the full-scale model shows a more uniform flow distribution. Additionally, the scaled-down models have lower turbulent viscosity, faster pressure wave attenuation, and a greater influence of viscous forces. Moreover, the water entry of the scaled-down models amplifies the scale effect on the Q criterion. These findings reveal the impact of scale effects on the water entry process and provide a reference for experimental design and numerical simulations.
AB - This study investigates the scale effects of structures with different scaling factors under identical water entry velocities based on a high-accuracy numerical simulation technique for flow fields. By comparing water entry velocity, cavity evolution characteristics, flow field parameters, and turbulence properties, the differences between scaled and full-scale models are analyzed. The results indicate that surface tension effects are enhanced in the scaled-down models, and different scaled models exhibit consistent dimensionless velocity at the same dimensionless time. The scaled-down models demonstrate higher local flow velocity, while the full-scale model shows a more uniform flow distribution. Additionally, the scaled-down models have lower turbulent viscosity, faster pressure wave attenuation, and a greater influence of viscous forces. Moreover, the water entry of the scaled-down models amplifies the scale effect on the Q criterion. These findings reveal the impact of scale effects on the water entry process and provide a reference for experimental design and numerical simulations.
KW - hydrodynamic force
KW - scale effect
KW - similarity
KW - unsteady flow
KW - water entry
UR - https://www.scopus.com/pages/publications/105030465774
U2 - 10.1109/CoMEA66280.2025.11241974
DO - 10.1109/CoMEA66280.2025.11241974
M3 - 会议稿件
AN - SCOPUS:105030465774
T3 - Proceedings of 2025 International Conference of Mechanical Engineering on Aerospace, CoMEA 2025
BT - Proceedings of 2025 International Conference of Mechanical Engineering on Aerospace, CoMEA 2025
PB - Institute of Electrical and Electronics Engineers Inc.
T2 - 2025 International Conference of Mechanical Engineering on Aerospace, CoMEA 2025
Y2 - 20 June 2025 through 22 June 2025
ER -