Methodological support for the training of UAV designers and operators


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Abstract

In this paper, we presented the developed concept for end-to-end training of designers and operators of UAVs on the basis of the use of specialized aircraft-type trainers.  The educational possibilities of the concept in terms of various training programs are discussed. A methodology for the selection of the main parameters of UAV taking into account the mutual effect of aerodynamics and weight was developed. It provided a wide range of specific requirements for UAVs for acquiring initial control skills in manual and automatic modes. The developed methodology is based on the takeoff-weight buildup equation modified with regard to the specific requirements for small-sized vehicles. This methodology also includes the process of choosing the most advantageous combination of geometric and kinematic parameters of an aircraft propeller using the isolated blade element theory. The methodology is implemented in PascalABC.NET language. A demonstrative example of selecting the main parameters of a training UAV for specific requirements is presented. The obtained basic technical characteristics of the UAV are given. A three-dimensional geometric model of the UAV was developed on the basis of the calculated data, and a prototype was manufactured. The flight parameters recorded through a series of test flights of the prototype are presented. The ways of using the described methodology for the development of training-and-research UAVs are discussed.

About the authors

O. E. Lukyanov

Samara National Research University

Author for correspondence.
Email: lukyanovoe@mail.ru

Candidate of Science (Engineering), Associate Professor of the Department of Aircraft Construction and Design

Russian Federation

D. V. Zolotov

Samara National Research University

Email: dmitriy.zolotov.98@mail.ru

Master’s Student, Institute of Aeronautical Engineering

Russian Federation

References

  1. Fedoseeva N.A., Zagvozdkin M.V. Promising areas of use of unmanned aerial vehicles. Nauchnyy Zhurnal. 2017. No. 9 (22). P. 26-29. (In Russ.)
  2. MChS Rossii. Bespilotnye letatel'nye apparaty [Digital source]. Available at: https://www.mchs.gov.ru/ministerstvo/o-ministerstve/tehnika/aviacionnaya-tehnika/bespilotnye-letatelnye-apparaty
  3. Boyko A. Oblasti primeneniya bespilotnikov [Areas of use of unmanned aerial vehicles]. Available at: http://robotrends.ru/robopedia/oblasti-primeneniya-bespilotnikov
  4. Professiya – vneshniy pilot. Kuda poyti uchit'sya na operatora drona v Rossii? [Remote pilot profession. How to become a drone operator in Russia]. Available at: https://aeronet.aero/press_room/analytics/2018_01_22_how_to_become_drone_operator_in_russia
  5. OOO «S"emka s Vozdukha» [OOO «Aerial cinematography»]. Available at: https://geodrone.su/
  6. V Samarskom aviatsionnom tekhnikume poyavilas' novaya spetsial'nost' – «Upravlenie dronami» [Digital source]. Available at: https://yandex.ru/turbo/1tv.ru/s/news/2019-11-06/375212-v_samarskom_aviatsionnom_tehnikume_poyavilas_novaya_spetsialnost_upravlenie_dronami
  7. Proektirovanie samoletov / pod red. S.M. Egera [Aircraft design / ed. by S.M. Eger]. Moscow: Mashinostroenie Publ., 1983. 616 p.
  8. Badyagin A.A., Eger S.M., Mishin V.F., Sklyanskiy F.I., Fomin N.A. Proektirovanie samoletov [Aircraft design]. Moscow: Mashinostroenie Publ., 1972. 516 p.
  9. Raymer D.P. Aircraft design: a conceptual approach. Washington: Amer. Inst. of Aeronautics a. Astronautics, 2012. 227 p.
  10. Roskam J. Airplane design. Part I: Preliminary sizing of airplanes. Lawrence Kansas: Design, Analisys and Research Corporation, 2017. 206 p.
  11. Balunov K.A., Chedrik V.V., Tuktarov S.A., Uskov V.M. Multidisciplinary topology-based optimization in design of aircraft structural layouts // 30-th Congress of the International Council of the Aeronautical Sciences, ICAS 2016 (September, 25-30, 2016, Daejeon, South Korea).
  12. Vyrypaev A.A., Kozlov D.M., Komarov V.A., Kuznetsov A.S. Selection of rational parameters of stepped wing with account for their weight and aerodynamic efficiency. VINITI no. 45-В2010. 28.01.2010. 40 p. (In Russ.)
  13. Wunderlich T. Multidisziplinärer entwurf und optimierung von flügeln für verkehrsflugzeuge. Deutscher Luft- und Raumfahrtkongress 2009 (08-10. Sept. 2009, Aachen, Deutschland). P. 1-10.
  14. Martins J.R.R.A., Kenway G.K.W., Brooks T. Multidisciplinary design optimization of aircraft configurations – Part 2: High-fidelity aerostructural optimization. Lecture series, Von Karman Institute for Fluid Dynamics, Sint-Genesius-Rode, Belgium, May 2016.
  15. Komarov V.A. Concurrent design. Ontology of Designing. 2012. No. 3 (5). P. 8-23. (In Russ.)
  16. Korolkov O. N. The equation and the area of existence of an airplane. All-Russian Scientific-Technical Journal «Polyot». 2001. No. 10. P. 45-52. (In Russ.)
  17. Bolkhovitinov V.F. Puti razvitiya letatel'nykh apparatov [Ways of aircraft evolution]. Moscow: Oborongiz Publ., 1962. 132 p.
  18. Lukyanov O.E., Espinosa Barsenas O.U., Zolotov D.V. Svidetel'stvo o gosudarstvennoy registratsii programmy dlya EVM «BPLADesign» [«UAV Design» computer program. State registration certificate]. No. 2021611018, 20.01.2021.
  19. Yur'ev B.N. Vozdushnye vinty [Airplane propellers]. Moscow: Gosmashmetizdat Publ., 1933. 400 p.
  20. Aleksandrov V.L. Vozdushnye vinty: ucheb. posobie dlya aviats. vuzov [Airplane propellers]. Moscow: Oborongiz Publ., 1951. 476 p.

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