Extensions of prescribed wake modelling for helicopter rotor BVI noise investigations

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• 作者：Berend G. van der Wall (1)
  
• 关键词：Prescribed wake ; Wake distortion ; Active rotor control ; BVI ; Rotor noise ; Rotor wake simulation ; Harmonic loading ; Fuselage/wake interference
• 刊名：CEAS Aeronautical Journal
• 出版年：2012
• 出版时间：April 2012
• 年：2012
• 卷：3
• 期：1
• 页码：93-115
• 全文大小：4538KB
• 参考文献：1. International Standards and Recommended Practices: Aircraft Noise, ICAO, Annex 16, vol. 1, USA (1988)
  2. Splettst??er, W.R., Schultz, K.-.J., Kube, R., Brooks, T.F., Booth, E.R. Jr., Niesl, G., Streby, O.: A higher harmonic control test in the DNW to reduce impulsive BVI noise. J. Am. Helicopter Soc. g class="a-plus-plus">39g>(4), 3-3 (1994)
  3. McCroskey, W.J.: Vortex wakes of rotorcraft. In: 33rd Aerospace Sciences Meeting and Exhibit, Reno, NV, USA, January (1995)
  4. Gray, R.B.: An aerodynamic analysis of a single-bladed rotor in hovering and low speed forward flight as determined from the smoke studies of the vorticity distribution in the wake. Princeton Aeronautical Engineering Department Report 356 (1956)
  5. Landgrebe, A.J.: An analytical and experimental investigation of helicopter rotor hovering performance and wake geometry characteristics, United States Army Air Mobility Research and Development Laboratory, USAAMRDL TR 71-24 (1971)
  6. Beddoes, T.S.: A Wake model for high resolution airloads. In: International Conference on Helicopter Basic Research, Triangle Park, NC, February (1985)
  7. Scully, M.P.: A method of computing helicopter vortex wake distortion, Massachusetts Institute of Technology, Report ASRL TR 138-1 (1967)
  8. Bhagwat, M.J., Leishman, J.G.: Stability, consistency and convergence of time-marching free-vortex rotor wake algorithms. J. Am. Helicopter Soc. g class="a-plus-plus">46g>(1), 59-1 (2001) g/10.4050/JAHS.46.59">CrossRef
  9. Lim, J.W.: Computational modeling of HART II blade–vortex interaction loading and wake system. J. Aircr. g class="a-plus-plus">45g>(3), 923-33 (2008) g/10.2514/1.31081">CrossRef
  10. Rankine, W.J.M.: On the mechanical principles of the action of propellers. Trans. Inst. Naval Archit. g class="a-plus-plus">VIg>, 13-0 (1865)
  11. Froude, W.: On the elementary relation between pitch, slip and propulsive efficiency. Trans. Inst. Naval Archit. g class="a-plus-plus">XIXg>, 47-7 (1878)
  12. Glauert, H.: A general theory of the Autogyro. Aeronautical Reseach Council, Reports and Memoranda 1111 (1926)
  13. Lock, C.N.H.: Further development of the Autogyro Theory. Aeronautical Reseach Council, Reports and Memoranda 1127 (1927)
  14. Drees, J.M.: A theory of airflow through rotors and its application to some helicopter problems. J. Helicopter Assoc. G. B. g class="a-plus-plus">3g>(2), 79-04 (1949)
  15. Johnson, W.: Helicopter Theory. Princeton University Press, Princeton (1980)
  16. Leishman, J.G.: Principles of helicopter aerodynamics. Cambridge University Press, New York (2000)
  17. Mangler, K.W., Squire, H.B.: The induced velocity field of a rotor. Aeronautical Reseach Council, Reports and Memoranda 2642 (1950)
  18. van der Wall, B.G.: The effect of HHC on the vortex convection in the wake of a helicopter rotor. Aerospace Science and Technology, vol. 4 (5), July (2000)
  19. Bronstein, I.N., Semendjajew, K.A.: Handbook of Mathematics, 5th edn. Springer, Berlin (2007)
  20. van der Wall, B.G., G?pel, C.: über den Einflu? der Rotorversuchsst?nde ROTEST und ROTOS auf die Rotordurchstr?mung im DNW, DLR-Mitteilungen 91-16, September (1991)
  21. van der Wall, B.G., Yin, J.: DLR’s S4 Rotor Code Validation With HART II Data: the baseline case. In: 1st International Forum on Rotorcraft Multidisciplinary Technology, Seoul, Korea, October (2007)
  22. van der Wall, B.G., Yin, J.: Simulation of active rotor control by comprehensive rotor code with prescribed wake using HART II Data, 65th AHS Forum, Grapevine, TX, USA, May (2009)
  23. van der Wall, B.G., Yin, J.: Cruise-speed BVI noise computation by comprehensive code and validation with HART I Data. In: 2nd International Forum on Rotorcraft Multidisciplinary Technology, Seoul, Korea, October (2009)
  24. van der Wall, B.G., Burley, C.L., Yu, Y.H., Pengel, K., Beaumier, P.: The HART II test—measurement of helicopter rotor wakes. Aerosp. Sci. Technol. g class="a-plus-plus">8g>(4), 273-84 (2004) g/10.1016/j.ast.2004.01.001">CrossRef
  25. Kube, R., Splettst??er, W.R., Wagner, W., Seelhorst, U., Yu, Y.H., Boutier, A., Mercker, E.: Initial results from the higher harmonic aeroacoustic rotor test (HART) in the German–Dutch Wind Tunnel. In: 75th AGARD Fluid Dynamics Panel Meeting and Symposium on Aerodynamics and Acoustics of Rotorcraft, Berlin, Germany, October (1994)
  26. Yin, J., Delfs, J.: Improvement of the DLR rotor aeroacoustic Code (APSIM) and its validation with analytic solution. In: 29th European Rotorcraft Forum, Friedrichshafen, Germany, September (2003)
  27. Lim, J.W.: The effect of fuselage and rotor hub on blade–vortex interaction airloads and rotor wakes. In: 36th European Rotorcraft Forum, Paris, France, September (2010)
  28. Kelly, M.E., Brown, R.: Predicting the wake structure of the HART II rotor using the vorticity transport model. In: 34th European Rotorcraft Forum, Liverpool, UK, September (2008)
  29. Park, J.-S., Sa, J.-H., You, Y.-H., Jung, S.N., Park, S.-H.: Fuselage effect in multibody dynamics/CFD coupled analysis for a rotor correlation in descending flight. In: 1st Asian Australian Rotorcraft Forum and Exhibition, Busan, Korea, February (2012)
  
• 作者单位：Berend G. van der Wall (1)
  
  1. DLR, Institute of Flight Systems, Helicopter, Lilienthalplatz 7, 38108, Braunschweig, Germany
  
• ISSN：1869-5590

文摘

The prediction of blade–vortex interaction noise is highly sensitive to the blade–vortex missdistance and thus requires the knowledge of the vortex position relative to the blade interacting with it. The generally accepted solution to the problem is to apply either free-wake codes (vortex lattice methods) or computational fluid dynamics (CFD) codes, both of which are very time consuming, especially CFD. Prescribed wake codes are computationally faster in comparison, since they are based on steady rotor operational conditions only, but they are considered to be not accurate enough due to the prescription of the geometry based on a few general parameters. First, they lack any wake geometry response due to variations in rotor loading distributions at constant thrust caused by, e.g., non-uniformity of the aerodynamic environment in forward flight, elastic blade motion, or by any means of active control. Second, wake deflections due to the presence of the fuselage are ignored. This paper provides an approximate solution to both problems, based on simple momentum theory considerations for the first problem, and based on the displacement flow of the fuselage for the second. This provides extensions for any existing prescribed wake model to account for rotor loading distribution and fuselage effects on the prescribed wake geometry to a first order of accuracy, sufficient for the investigations of the sensitivity analysis of noise radiation due to variations of blade design or due to applications of active control.