Numerical Study of the Main Rotor Wake Structures and Induced Velocity Fields at the Tail Rotor Location When Flying Near the Ground

Ignatkin, Yuri Mikhailovich; Makeev, P. V.; Shomov, A. I.; Ivchin, V.A.

doi:10.15866/irease.v14i4.19744

IREASE

2021

DOI: 10.15866/irease.v14i4.19744

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Numerical Study of the Main Rotor Wake Structures and Induced Velocity Fields at the Tail Rotor Location When Flying Near the Ground

Yuri Mikhailovich Ignatkin

P. V. Makeev

A. I. Shomov

et al.

Abstract: The distance from the rotor's hub to the ground surface in the range of H = 6-16 m and the values of free stream (flight) velocity in the range of V = 0-15 m/s are considered. The results of the visualization for both rotor wake shapes and streamlines are obtained. The influence of the ground proximity on the rotor wake shape, including the formation of "supervortex" and "ground vortex" structures are analyzed. The induced velocity fields of the main rotor in the area of the tail rotor location for various azi… Show more

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2024

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Investigation of Helicopter Blade Tip Configuration during Hover Flight Employing Computational Fluid Dynamics

Stouti,

Lahlou,

Lagrat

et al. 2024

Modelling and Simulation in Engineering

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Our research focused on investigating the influence of rotor blade tip geometry on the aerodynamic performance of helicopters during hover flight, with the goal of enhancing overall efficiency. Through computational fluid dynamics (CFD) analysis using the Bell 212 helicopter configuration, we evaluated four different blade tip geometries: rectangular, anhedral, swept, and parabolic. Our study revealed significant insights into the aerodynamic characteristics of each geometry, including pressure distribution and airflow patterns. Crucially, we observed improvements in the thrust coefficient CT and stability, leading to enhanced efficiency, particularly with the optimized blade tip geometry identified through our comparative analysis. These findings offer valuable guidance for designing more efficient helicopter rotors.

show abstract

Investigation of Helicopter Blade Tip Configuration during Hover Flight Employing Computational Fluid Dynamics

Stouti,

Lahlou,

Lagrat

et al. 2024

Modelling and Simulation in Engineering

View full text Add to dashboard Cite

show abstract

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Numerical Study of the Main Rotor Wake Structures and Induced Velocity Fields at the Tail Rotor Location When Flying Near the Ground

Cited by 1 publication

References 17 publications

Investigation of Helicopter Blade Tip Configuration during Hover Flight Employing Computational Fluid Dynamics

Investigation of Helicopter Blade Tip Configuration during Hover Flight Employing Computational Fluid Dynamics

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