NUMERICAL INVESTIGATION OF TIP VORTEX REDUCTION IN A TOROIDAL PROPELLER USING CFD

J.I. Kim; S.W. Jung; B.G. Baik; J.W. Ahn; S.H. Kim; M.E. Kim; I.R. Park

doi:10.6112/kscfe.2025.30.3.055

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Original Article

NUMERICAL INVESTIGATION OF TIP VORTEX REDUCTION IN A TOROIDAL PROPELLER USING CFD CFD를 이용한 원환체 프로펠러 날개 끝 와류 감소 연구

30 September 2025. pp. 55-73

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Abstract

This paper presents a numerical investigation aimed at improving the hydrodynamic performance of a toroidal propeller and reducing tip vortex formation by varying three key design parameters: pitch ratio, camber, and vertical angle. As with conventional open propellers, the pitch ratio and camber significantly influence thrust and torque characteristics, while the vertical angle plays a critical role in both propulsive performance and tip vortex suppression. Through optimization of these parameters, the modified propeller achieves thrust performance comparable to that of the original design, with reduced torque and improved efficiency. Additionally, tip vortex generation is significantly reduced, demonstrating the potential of the toroidal propeller to effectively overcome the inherent tip vortex issues associated with conventional open propellers.

Keywords

Toroidal propeller

Propeller open water performance

Tip vortex

Computational fluid dynamics

RANS method

키워드

원환체 프로펠러

프로펠러 단독성능

날개 끝 와류

전산유체역학

RANS법

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Information

Publisher :Korean Society for Computational Fluids Engineering
Publisher(Ko) :한국전산유체공학회
Journal Title :Journal of Computational Fluids Engineering
Journal Title(Ko) :한국전산유체공학회지
Volume : 30
No :3
Pages :55-73
Received Date : 2025-05-27
Revised Date : 2025-08-13
Accepted Date : 2025-09-04
DOI :https://doi.org/10.6112/kscfe.2025.30.3.055

Journal of Computational Fluids Engineering ISSN:1598-6071(Print) 3022-6252(Online) 한국전산유체공학회지

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