PREDICTION OF FUSELAGE FLOW SEPARATION AND DRAG CHARACTERISTICS OF A ROTORCRAFT USING THE LATTICE BOLTZMANN METHOD

D. Jeong; K.T. Park; C. Kim; S.H. Park; H. Jung; H. Lee

doi:10.6112/kscfe.2026.31.1.001

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2026 Vol.31, Issue 1 Next Page

Original Article

PREDICTION OF FUSELAGE FLOW SEPARATION AND DRAG CHARACTERISTICS OF A ROTORCRAFT USING THE LATTICE BOLTZMANN METHOD LBM 해석을 이용한 회전익기 동체의 박리 유동 및 항력 특성 분석

31 March 2026. pp. 1-22

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Abstract

This study investigates the flow separation behavior on the upper and lower fuselage surfaces of a next-generation high-speed rotorcraft and its influence on drag characteristics using lattice Boltzmann Method (LBM) simulations. The LBM results were validated against wind-tunnel experiments. The analysis revealed that adverse pressure gradients induced massive flow separation on both the upper engine-cowling and lower ramp regions. Early separation occurred on the upper surface, whereas delayed separation appeared on the lower surface. The separated flows from these regions interacted in the aft fuselage, forming large-scale wake structures that hindered pressure recovery and consequently increased pressure drag. As the angle of attack increased, the separation point on the upper surface moved forward, while that on the lower surface shifted rearward, exhibiting opposite trend. These results provide fundamental insights for designing drag-reduction devices and optimizing fuselage configurations in future rotorcraft development.

Keywords

Fuselage flow separation

Drag reduction

Aerodynamic interaction

Computational fluid dynamics

Lattice-Boltzmann method

키워드

동체 유동 박리

항력 저감

공력 상호작용

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 : 31
No :1
Pages :1-22
Received Date : 2025-10-16
Revised Date : 2026-03-19
Accepted Date : 2026-03-20
DOI :https://doi.org/10.6112/kscfe.2026.31.1.001

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

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