Abstract
Flow field around rotors in axial flight is known to be complex especially in steep descent where the rotor is operating inside its own wake. It is often reported that, in this flight condition, the rotor is susceptible to severe wake interactions causing unsteady blade load, severe vibration, loss of performance, as well as poor control and handling. So far, there is little data from experimental and numerical analysis available for rotors in axial flight. In this paper, the steady Reynolds-Averaged Navier-Stokes Computational Fluid Dynamics solver Helicopter Multi-Block was used to predict the performance of rotors in axial flight. The main objective of this study was to improve the basic knowledge about the subject and to validate the flow solver used. The results obtained are presented in the form of surface pressure, rotor performance parameters, and vortex wake trajectories. The detailed velocity field of the tip vortex for a rotor in hover was also investigated, and a strong self-similarity of the swirl velocity profile was found. The predicted results obtained when compared with available experimental data showed a reasonably agreement for hover and descent rate, suggesting unsteady solution for rotors in vortex-ring state.
Highlights
In steep descent where helicopter enters vortex-ring state (VRS), a rotor descends into its own wake
Several experiments and computational studies for low speed descending flight have been reported in literature, but relatively a few show detailed quantitative measurements of rotor performance and blade aerodynamic characteristics
The aerodynamic performance and wake geometry of the Caradonna UH-1H rotor were computed for a range of ascend rates, Vv /Vtip, from hover to ascending rate of 0.04
Summary
In steep descent where helicopter enters vortex-ring state (VRS), a rotor descends into its own wake. For a low ascending flight case of Vv /Vtip = 0.04, the primary blade tip vortex predicted by HMB is found to be displaced 2.634 chord downstream the rotor plane.
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