Abstract
A computational fluid dynamics (CFD) trimming method based on wind tunnel and flight test data is proposed. Aerodynamic coefficients obtained for a helicopter rotor using this method were compared with both experimental data from a test report and CFD results based on the control parameters that were reported in the same document. The method applies small disturbances to the collective pitch angle, the lateral cyclic pitch angle and the longitudinal cyclic pitch angle of the helicopter’s main rotor during forward flight to analyze the effects of each disturbance on the thrust coefficient, the pitching moment coefficient and the rolling moment coefficient of the rotor. Then, by solving a system of linear equations, the collective pitch angle, the lateral cyclic pitch angle and the longitudinal cyclic pitch angle of the main rotor in the CFD trim state are obtained. The AH-1G rotor is used in this paper. NASA has conducted a comprehensive flight test program on this model and has published detailed test reports. Using this method, the pitch moment and the roll moment can be corrected to almost zero and the calculated thrust coefficient is more consistent with the test data when compared with results from direct CFD simulations.
Highlights
As the most important part of a helicopter, the main rotor provides thrust, lift and the control force for the aircraft
This environment includes the interactions of strong vortices with each other and with the rotor blades, the formation of a complex spiral wake behind the rotor, a transition between laminar flow and turbulence, wide variations in the Mach and Reynolds numbers on the blade, the local shock generated by an advancing blade and the airflow separation generated by a retreating blade.[1,2]
A new computational fluid dynamics (CFD) trimming method is proposed for a helicopter rotor in forward flight and the rotor trimming process is introduced in detail
Summary
As the most important part of a helicopter, the main rotor provides thrust, lift and the control force for the aircraft. An extremely complex unsteady flow dynamic environment is formed within the flow field of a helicopter during forward flight. This environment includes the interactions of strong vortices with each other and with the rotor blades, the formation of a complex spiral wake behind the rotor, a transition between laminar flow and turbulence, wide variations in the Mach and Reynolds numbers on the blade, the local shock generated by an advancing blade and the airflow separation generated by a retreating blade.[1,2] These aerodynamic problems mean that research into the aerodynamic performance of helicopter rotors presents considerable challenges. When classical problems such as airframe drag reduction are considered, experimental methods using wind tunnels
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