Abstract
The tail rotor of a helicopter operating under low-speed crosswind undergoes highly complex flow due to the interaction between the main rotor, fuselage, and tail rotor system. In this study, numerical simulations have been conducted on the complete configuration of a helicopter with a ducted fan tail rotor system (comprising a main rotor, ducted fan tail rotor, fuselage, and empennage) to analyze the wake interaction in hovering flight under various crosswind directions. The flow characteristics around the tail rotor, the tail rotor thrust, and the yawing moment of the helicopter are investigated and evaluated. The aerodynamic forces are compared with those of a helicopter with an open-type tail rotor. The results indicate that the aerodynamic performance of the ducted fan tail rotor is highly affected by the wakes of both the main rotor and port wing. Nevertheless, the helicopter with a ducted fan tail rotor is observed to be much more directionally stable under various crosswind directions, than that with an open-type tail rotor. This is because the rotor is protected by the fixed part of the tail rotor system in the former case.
Highlights
A helicopter operates in a highly complex and unsteady flowfield due to the substantial interference among its components
The Federal Aviation Administration (FAA) Advisory Circular states that loss of tail rotor effectiveness (LTE) is a critical aerodynamic characteristic, which can result in the loss of aircraft control [2]
A numerical analysis has been conducted for the complete configuration of a helicopter with a ducted fan tail rotor
Summary
A helicopter operates in a highly complex and unsteady flowfield due to the substantial interference among its components. The performance of the tail rotor, which governs directional stability, is influenced considerably by the wake and vortex generated by the main rotor, fuselage, and incoming flow. Several helicopters that comprise a main rotor and open-type tail rotor exhibit limitations in direction control at low-speeds [1]. The Federal Aviation Administration (FAA) Advisory Circular states that loss of tail rotor effectiveness (LTE) is a critical aerodynamic characteristic, which can result in the loss of aircraft control [2]. In this regard, LTE is one of the prominent causes of helicopter accidents. A total of 82 out of 547 accidents between 1993 and 2004 involved LTE during hovering and lowspeed flights [3]
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