소산이 고려된 보오텍스 모델과 버블 이론을 이용한 수중익 날개 끝 보오텍스 캐비테이션 거동및 소음의 수치적 해석

Abstract

Cavitation is the dominant noise source of the marine vehicle. Of the various types of cavitation, tip vortex cavitation is the first appearance type of marine propeller cavitation and it generates high frequency noise. Therefore, prediction of tip vortex cavitation behavior and noise characteristics is very important in military and merchant shipping sectors. In this study, tip vortex cavitation behavior and noise are numerically investigated. A numerical scheme using Eulerian flow field computation and Lagrangian particle trace approach is applied to simulate the tip vortex cavitation on the hydrofoil. Vortex flow field is simulated by combined Moore and Saffman’s vortex core radius equation and Sculley vortex model. Tip vortex cavitation behavior is analyzed by coupled Rayleigh-Plesset equation and trajectory equation. Experimental nuclei population data are converted to produce computational nuclei population and these nuclei are distributed and released in the vortex flow result. Vortex cavitation trajectories and radius variations are computed according to nuclei initial size. Noise is analyzed using time dependent cavitation bubble position and radius data. This study may lay the foundation for future work on vortex cavitation study and it will provide a basis for proper underwater propeller noise control strategies.