COMPARATIVE ANALYSIS OF AERODYNAMIC AND ACOUSTIC PERFORMANCE BETWEEN DISTRIBUTED ELECTRIC PROPULSION AND EQUIVALENT SINGLE PROPELLER

H.S. Song; Y.H. Hwang; R.S. Myong; H. Lee

doi:10.6112/kscfe.2025.30.4.001

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2025 Vol.30, Issue 4 Next Page

Original Article

COMPARATIVE ANALYSIS OF AERODYNAMIC AND ACOUSTIC PERFORMANCE BETWEEN DISTRIBUTED ELECTRIC PROPULSION AND EQUIVALENT SINGLE PROPELLER 분산전기추진시스템과 등가 단일 프로펠러 간의 공력 및 소음 성능 비교 연구

31 December 2025. pp. 1-18

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Abstract

Distributed electric propulsion(DEP) has attracted attention as a sustainable alternative to conventional propulsion systems in pursuit of carbon-neutral aviation. Although DEP systems offer advantages such as improved aerodynamic control and reduced noise emissions, the complex flow interactions among multiple rotors and the wing surface should be investigated to ensure reliable performance prediction. This study presents a comparative numerical analysis of aerodynamic and acoustic performance between a single-propeller configuration and a DEP system under equivalent thrust and tip Mach number conditions. Flow simulations were conducted using the Lattice Boltzmann Method(LBM), and far-field acoustic predictions were obtained via the Ffowcs Williams-Hawkings(FW-H) method under impermeable surface assumptions. The DEP configuration with three propellers generated a more spanwise-uniform suction distribution, yielding a 5-8% increase in lift coefficient compared to the single-propeller case. However, drag was slightly higher due to increased friction from multiple rotors. Moreover, the DEP system achieved an average noise reduction of 2-3 dB in Overall Sound Pressure Level(OASPL), with a maximum reduction of 4.1 dB observed in the downward direction. These results demonstrate that DEP systems can offer aerodynamic benefits while significantly reducing noise emissions, supporting their applicability to next generation low noise air vehicle designs.

Keywords

Sustainable aircraft

Distributed electric Propulsion

Aerodynamic interference

Aerodynamic noise

Computational fluid dynamics

Lattice-Boltzmann method

키워드

친환경 항공기

분산전기추진

공력 간섭

공력 소음

전산유체역학

격자 볼츠만 법

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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 :4
Pages :1-18
Received Date : 2025-07-04
Revised Date : 2025-11-27
Accepted Date : 2025-12-24
DOI :https://doi.org/10.6112/kscfe.2025.30.4.001

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

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