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A comprehensive rotary-wing data base for code validation: the HART II international workshop

Published online by Cambridge University Press:  27 January 2016

B. G. van der wall*
Affiliation:
Institute of Flight Systems, Helicopter, German Aerospace Center (DLR), Braunschweig, Germany

Abstract

The HART II test of 2001 provided a significant and comprehensive database of rotor loads, blade motion, blade pressure distribution, acoustic signature and flow field data. A sub-set of these were released for public access worldwide and an International HART II Workshop was established in 2005. This Workshop, open to the international rotorcraft community, has been held since then at both the AHS Annual Forum as well as the European Rotorcraft Forum. Following the requests of participants, the HART II International Workshop database has been undergoing continuous development. This paper describes the current content and status of the data and the documentation material provided within the workshop database.

Type
Research Article
Copyright
Copyright © Royal Aeronautical Society 2011

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References

1. van der wall, B.G., Burley, C.L., Yu, Y.H., Pengel, K. and Beaumier, P. The HART II Test – Measurement of helicopter rotor wakes, Aerospace Science and Technology, 2004, 8, (4), pp 273284.CrossRefGoogle Scholar
2. Schneider, O. Analysis of SPR Measurements of HART II, Aerospace Science and Technology, 2005, 9, (5), pp 409420.CrossRefGoogle Scholar
3. van der wall, B.G. and Richard, H. Analysis methodology for 3C PIV data of rotary wing vortices, Experiments in Fluids, 2006, 40, (5), pp 798812.CrossRefGoogle Scholar
4. Perez, G., Bailly, J. and Rahier, G. Using the HART II Database to improve BVI noise prediction, J American Helicopter Society, 2008, 53, (1), pp 5667.CrossRefGoogle Scholar
5. Burley, C.L., Brooks, T.F., Van Der Wall, B.G., Richard, H., Raffel, M., Beaumier, P., Delrieux, Y., Lim, J.W., Yu, Y.H., Tung, C., Pengel, K. and Mercker, E. Rotor wake vortex definition using 3C-PIV measurements – corrected for vortex orientation, 9th AIAA/CEAS Aeroacoustics Conference, Paper 3175, Hilton Head, SC, USA, 2003.Google Scholar
6. Lim, J.W., Tung, C., Yu, Y.H., Burley, C.L., Brooks, T.F., Boyd, D., Van Der Wall, B.G., Schneider, O., Richard, H., Raffel, M., Beaumier, P., Delrieux, Y., Pengel, K. and Mercker, E. HART II: Prediction of Blade-Vortex Interaction Loading, 29th European Ro-torcraft Forum, Friedrichshafen, Germany, 2003.Google Scholar
7. Lim, J.W., Nygaard, T.A., Strawn, R. and Potsdam, M. BVI Airloads prediction using CFD/CSD loose coupling, 4th AHS Vertical Lift Aircraft Design Conference, San Francisco, CA, USA, 2006.Google Scholar
8. Splettstöber, W.R., Kube, R., Wagner, W., Seelhorst, U., Boutier, A., Micheli, F., Mercker, E. and Pengel, K. Key results from a higher harmonic control aeroacoustic rotor test (HART), J American Helicopter Society, 1997, 42, (1), pp 5878.10.4050/JAHS.42.58CrossRefGoogle Scholar
9. Heyson, H.H. FORTRAN programs for calculating wind-tunnel boundary interference, NASA-TM-X-1740, 1969.Google Scholar
10. Dietz, M., Krämer, E. and Wagner, S. Tip vortex conservation on a main rotor in slow descent flight using vortex-adapted Chimera grids, 24th AIAA Applied Aerodynamics Conference, Paper 3478, San Francisco, CA, USA, 2006.CrossRefGoogle Scholar
11. Hashimoto, A., Nakamura, Y., Saito, S., Aoyama, T. and Yang, C. Aeroelastic simulation of HART II model using moving overlapped grid approach, 32nd European Rotorcraft Forum, Maastricht, Netherlands, 2006.Google Scholar
12. Kelly, M.E., Duraisamy, K. and Brown, R.E. Predicting blade vortex interaction, airloads and acoustics using the vorticity transport model, AHS Specialists’ Conference on Aeromechanics, San Francisco, CA, USA, 2008.Google Scholar
13. Lim, J.W. An assessment of rotor dynamics correlation for descending flight using CFD/CSD coupled analysis, 64th Annual Forum of the AHS, Montreal, Canada, 2008.Google Scholar
14. Johnson, W. CAMRAD II, Comprehensive analytical model of rotor-craft aerodynamics and dynamics, Johnson Aeronautics, Palo Alto, CA, USA, 1992.Google Scholar
15. Benoit, B., Gaulene, P. and Martin, P. HOST – Helicopter overall simulation tool, User Manual, Eurocopter France, Marignane, France, 1997.Google Scholar
16. van der wall, B.G. An analytical model of unsteady profile aerodynamics and its application to a rotor simulation program, 15th European Rotorcraft Forum, Amsterdam, Netherlands, 1989.Google Scholar
17. van der wall, B.G. The effect of HHC on the vortex convection in the wake of a helicopter rotor, Aerospace Science and Technology, 2000, 4, (5), pp 320336.CrossRefGoogle Scholar
18. Perez, G. and Costes, M. A new aerodynamic and acoustic computation chain for BVI noise prediction in unsteady flight conditions, 60th Annual Forum of the AHS, Baltimore, MD, USA, 2004.Google Scholar
19. Lim, J.W. And van der wall, B.G. Investigation of the effect of a multiple trailer free wake model for descending flights, 61st Annual Forum of the AHS, Grapevine, TX, USA, 2005.Google Scholar
20. van der wall, B.G. and Yin, J. DLR’s S4 rotor code validation with HART II data: the baseline case, 1st International Forum on Rotorcraft Multidisciplinary Technology, Seoul, Korea, 2007.Google Scholar
21. van der wall, B.G. and Yin, J. Simulation of active rotor control by comprehensive code with prescribed wake using HART II data, 65th Annual Forum of the AHS, Grapevine, TX, USA, 2009.Google Scholar
22. Bailly, J., Delrieux, Y. and Beaumier, P. HART II: Experimental analysis and validation of ONERA methodology for the prediction of blade-vortex Interaction, 30th European Rotorcraft Forum, Marseille, France, 2004; 61st Annual Forum of the AHS, Grapevine, TX, USA, 2005.Google Scholar
23. Perez, G. and Bailly, J. Using the HART II Data base to improve BVI noise prediction, 32nd European Rotorcraft Forum, Maastricht, Netherlands, 2006.Google Scholar
24. Rodriguez, B. Numerical simulation of blade vortex Interaction and vortex ring state aerodynamics using a fully time marching unsteady wake model, 33rd European Rotorcraft Forum, Kasan, Russia, 2007.Google Scholar
25. Sim, B.W. and Lim, J.W. Blade-vortex interaction (BVI) noise and airload prediction using loose aerodynamic/structural coupling, 62nd Annual Forum of the AHS, Phoenix, AZ, USA, 2006.Google Scholar
26. Boyd, D.D. HART-II Acoustic predictions using a coupled CFD/CSD method, 65th Annual Forum of the AHS, Grapevine, TX, USA, 2009.Google Scholar
27. Lim, J.W. and Strawn, R.C. Computational modeling of HART II blade-vortex interaction loading and wake system, 45th AIAA Aerospace Sciences Meeting and Exhibit, Reno, Nevada, USA, 2007; AIAA J Aircr, 2008, 45, (3), pp 923933.Google Scholar
28. Kelly, M.E. and Brown, R.E. The effect of blade aerodynamic modelling on the prediction of the blade airloads and the acoustic signature of the HART II rotor, 35th European Rotorcraft Forum, Hamburg, Germany, 2009 Google Scholar
29. Min, B.-Y., Sankar, L., Prasad, J.V.R. and Schrage, D. A Physics-based investigation of gurney flaps for rotor vibration reduction, 65th Annual Forum of the AHS, Grapevine, TX, USA, 2009.Google Scholar