On the generation of a helicopter aerodynamic database

The present study is one of the first attempts to exploit the GOAHEAD data base to perform a code-tocode evaluation on complete helicopter aerodynamics. The numerical results of two GOAHEAD partners, the German Aerospace Center (DLR) and Politecnico di Milano (PoliMi) are presented and compared to experimental measurements. The study also addresses an evaluation of two different approaches to predict helicopter flows. The first, applied by DLR, accounts for rotor trim and elastic effects by weak fluid-structure coupling. The PoliMi approach, on the other hand, enforces a prescribed kinematics, taken directly from the experiment, on a rigid blade. The simulations refer to a complete helicopter windtunnel model, featuring a scaled NH90 fuselage, the ONERA 7AD main rotor, a scaled BO105 tail rotor, a rotor hub and a pylon, all located inside the 8 m × 6 m test section of the DNW low-speed wind tunnel. The flight conditions correspond to cruise flight at Ma = 0.204 and fuselage attitude α = −2.5 •. The comparisons demonstrate the capability of present unsteady RANS solvers to predict flow fields around complete helicopters.

show abstract

“…Three-dimensional velocity field PIV data were gathered during the experimental campaign [25] in several cross-planes, described in Fig. 15.…”

Section: Flow Fieldmentioning

confidence: 99%

CFD prediction of air flow past a full helicopter configuration

Biava¹,

Khier

Vigevano

2012

Aerospace Science and Technology

View full text Add to dashboard Cite

show abstract

“…The experiments comprised measurements of the global forces of the main rotor and fuselage, normal force and bending moments acting on the horizontal stabiliser, axial force and torque of the tail rotor, steady and unsteady pressures, and boundary layer transition positions. Furthermore, the position of flow separation, the velocity fields of the model wake, around the fuselage and on the upper surface of the advancing and retreating rotor blades, the vortex trajectories and the elastic deformations of the main and tail rotor blades were investigated (Raffel et al 2009. This paper summarises the flow field measurements of the GOAHEAD test campaign jointly performed by CIRA, DLR and DNW.…”

Section: Abbreviationsmentioning

confidence: 99%

A comprehensive PIV measurement campaign on a fully equipped helicopter model

2011

View full text Add to dashboard Cite

The flow field around a helicopter is characterised by its inherent complexity including effects of fluidstructure interference, shock-boundary layer interaction, and dynamic stall. Since the advancement of computational fluid dynamics and computing capabilities has led to an increasing demand for experimental validation data, a comprehensive wind tunnel test campaign of a fully equipped and motorised generic medium transport helicopter was conducted in the framework of the GOAHEAD project. Different model configurations (with or without main/tail rotor blades) and several flight conditions were investigated. In this paper, the results of the three-component velocity field measurements around the model are surveyed. The effect of the interaction between the main rotor wake and the fuselage for cruise/tail shake flight conditions was analysed based on the flow characteristics downstream from the rotor hub and the rear fuselage hatch. The results indicated a sensible increment of the intensity of the vortex shedding from the lower part of the fuselage and a strong interaction between the blade vortex filaments and the wakes shed by the rotor hub and by the engine exhaust areas. The pitch-up phenomenon was addressed, detecting the blade tip vortices impacting on the horizontal tail plane. For high-speed forward flight, the shock wave formation on the advancing blade was detected, measuring the location on the blade chord and the intensity. Furthermore, dynamic stall on the retreating main rotor blade in high-speed forward flight was observed at r/R = 0.5 and 0.6. The analysis of the substructures forming the dynamic stall vortex revealed an unexpected spatial concentration suggesting a rotational stabilisation of large-scale structures on the blade. Abbreviations CFDComputational fluid mechanics DEHS Di-ethyl-hexyl-sebacat DS Dynamic stall GOAHEAD Generation of advanced helicopter experimental aerodynamic database for CFD code validation PIV Particle image velocimetry WT Wind tunnel Symbols a Speed of sound, m/s c Blade chord, m L Fuselage length, m L m Measurement volume length, m M Mach number r Radial coordinate, m r v Vortex radius, m r c Vortex core radius, m R Rotor radius, m t Time, s

show abstract

“…Sophisticated experimental techniques for the determination of the skin-friction distribution (thereby also detecting transition) have to be developed in order to improve and validate numerical prediction and design methods. The complex hot-film anemometry has successfully been used in order to investigate the unsteady boundary-layer transition on pitching airfoils [1,2] and large-scale helicopter rotor models in forward-flight configurations [3]. Recently, considerable efforts have been focused toward optical techniques for their high spatial resolution and relative ease of use.…”

Section: Introductionmentioning

confidence: 99%