MODERN PROBLEMS OF AEROACOUSTICS OF PROPELLER-DRIVEN FIXED-WING AIRCRAFTS


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Abstract

The modern classification of noise sources of propeller-driven fixed-wing aircraft is considered. Competitive community noise levels for single- and twin-engine for the projected light propeller-driven aircraft are formulated. An approach to community noise regulation of propeller-driven fixed-wing unmanned aerial vehicles is proposed. Modern approaches to assessing the community noise of propeller-driven fixed-wing aircraft are considered.

About the authors

M. A. Pogosyan

Moscow Aviation Institute (National Research University)

Email: moshkov89@bk.ru
Russian Federation, Volokolamskoye shosse, 4, Moscow, 125993, Russian Federation

P. A. Moshkov

Moscow Aviation Institute (National Research University)

Author for correspondence.
Email: moshkov89@bk.ru
Russian Federation, Volokolamskoye shosse, 4, Moscow, 125993, Russian Federation

References

  1. Gutin L.Ya. About the sound field of a rotating propeller. Journal of Technical Physics. 1936. vol.6. no. 5. pp. 899–909. (in Russian)
  2. Yudin E.Ya. On vortex noise of rotating rods. Journal of Technical Physics. 1944. vol.12. no. 9. pp.561–567. (in Russian)
  3. Barry F.W., Magliozzi B. Noise detectability prediction method for low tip speed propellers. Wright-Patterson AFB, Ohio, AFAPL-TR-71-37, 1971.
  4. Hanson D.B. Compressible helicoidal surface theory for propeller aerodynamics and noise. AIAA Journal. 1983. Vol. 21. No. 6. pp. 881–889.
  5. Moshkov P.A., Samokhin V.F., Yakovlev A.A. Selection of an audibility criterion for propeller driven unmanned aerial vehicle. Russian Aeronautics. 2018. vol. 61. no 2. pp. 149-155.
  6. Moshkov P., Samokhin V., Yakovlev A. About the community noise problem of the light propeller aircraft, Akustika. 2019. Vol. 34. pp. 68–73.
  7. Kopyev V.F., Zaitsev M.Yu., Velichko S.A., Dolotovsky A.V., Shevyakov V.I. On determining the aerodynamic noise of the main elements of a full-scale aircraft using a multimicrophone antenna and beamforming algorithms. Reports of the Russian Academy of Sciences. Physics, technical sciences. 2022. Vol. 506. No. 1. pp. 68-81. (in Russian)
  8. Dmitriev V.G. Samokhin V.F. Complex of algorithms and programs for calculating aircraft community noise. TsAGI Science Journal. 2014. vol. 45. vol. 2. pp. 136–157. (in Russian)
  9. Moshkov P.A. Classification of community noise source by light propeller aircrafts. Scientific and technical Volga region bulletin. 2015. no 4. pp. 101-106. (in Russian)
  10. Moshkov P.A. Acoustic characteristics of aircraft piston engines. Russian Aeronautics. 2020. vol. 63. no. 4. pp. 568-574.
  11. Ismagilov F.R., Varyukhin A.N., Vavilov V.E., Bekuzin V.I., Gusakov D.V. System Approach to Electric Machines Development for Aviation Hybrid Propulsion Systems under Economic Crisis. IEEE Transactions on Aerospace and Electronic Systems. 2021. vol. 57. no. 6. pp. 3768–3781.
  12. Adu-Gyamfi B.A., Good C. Electric aviation: A review of concepts and enabling technologies. Transportation Engineering. 2022. vol. 9. no. 100134. doi: 10.1016/j.treng.2022.100134
  13. Moshkov P.A., Samokhin V.F., Yakovlev A.A. Problem of the community noise reduction for aircraft with open rotor engines. Russian Aeronautics. 2018. vol. 61. no 4. pp. 647-650.
  14. Moshkov P.A. Study of the wing noise of an unmanned aerial vehicle. Russian Aeronautics. 2021. vol. 64. no. 2. pp. 240-247.
  15. Moshkov P.A., Samokhin V.F. Investigation of the effect of the gap between the pusher propeller and the wing on the community noise level of a light aircraft. TsAGI Science Journal. 2016. vol. 47. no. 6. pp. 55-60.
  16. Dmitriev V.G., Samokhin V.F., Khaletskii Yu.D. Effect оf technical progress оn the airplane noise. Polet. 2019. no. 4. pp. 3-18. (in Russian)
  17. Kopiev V.F. The main milestones in the development of acoustic department of TsAGI are considered. Polet. 2018. no. 11. pp. 60-69. (in Russian)
  18. Denisov S.L., Ostrikov N.N., Granich V.Y. Problems of aviation power plants noise reduction by means of shielding effect. Acoustical Physics. 2021. vol. 67. no. 3. pp. 293-297.
  19. Dmitriev V.G., Samokhin V.F., Moshkov P.A. Acoustics of light propeller-driven aircraft. Polet. 2022. no 3. pp. 3-12. (in Russian)
  20. Moshkov P.A., Samokhin V.F. Problems of light propeller-driven airplane design with regard to community noise requirements. Aerospace MAI Journal. 2021. vol. 28. no 1. pp. 19–34. (in Russian)
  21. Environmental Protection. Annex 16 to the Convention on International Civil Aviation, Montreal. Canada. ICAO. 2011. Vol. 1 Aircraft Noise. 227 p.
  22. Herniczek M.K., Feszty D., Meslioui S., Park J. Applicability of Early Acoustic Theory for Modern Propeller Design. 23rd AIAA/CEAS Aeroacoustics Conference. No. AIAA 2017-3865. doi: 10.2514/6.2017-3865
  23. Timushev S., Yakovlev A., Moshkov P. Numerical simulation of the light aircraft propeller noise under static condition. Akustika. 2021. vol. 41. pp. 100-106.
  24. Bobkov V.G., Kozubskaya T.K., Kudryavtseva L.N., Tsvetkova V.O. Hybrid dynamic mesh redistribution – immersed boundary method for acoustic simulation of flow around a propeller. Supercomputing Frontiers and Innovations. 2022. Vol. 9. No. 4. pp. 69–84. doi: 10.14529/jsfi220407
  25. Kopiev V.F., Titarev V.A., Belyaev I.V. Development of a methodology for propeller noise calculation on high-performance computer. TsAGI Science Journal. 2014. V. 45. No. 3-4. pp. 293-327. doi: 10.1615/TsAGISciJ.2014011857
  26. Samokhin V.F. Semiempirical method for estimating the noise of a propeller. Journal of Engineering Physics and Thermophysics. 2012. vol. 85. no 5. pp. 1157-1166.
  27. Moshkov P.A., Samokhin V.F. Integral model of noise of an engine-propeller power plant. Journal of Engineering Physics and Thermophysics. 2018. vol. 91. no 2. pp. 332-338.
  28. Moshkov P.A. Empirical method of predicting aviation piston engine noise. Vestnik of the Samara State Aerospace University. 2016. vol. 15. no. 2. pp. 152-161. doi: 10.18287/2412-7329-2016-15-2-152-161 (in Russian)

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Journal of Dynamics and Vibroacoustics

ISSN 2409-4579 (Online)

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