Models of early stages of design of trunk-route passenger airplanes with taking families into account

There is a tight connection between the Pre-Design (development of requirements for the designed airplane) and Conceptual Design stages while creating a new aircraft. Taking this connection into account would result in the design of more optimal aircraft that would have the appropriate advantage during operation. Previously when the ability to take such interconnections into the account was lacking the designers were forced to allocate certain reserves in the project based on previous design experience. The advancement of design, modeling and manufacturing methods allowed transitioning from allocating these reserves as means for possible error compensation to their planning or management. In particular, such planned reserves should be allocated in wing and landing gear at the Conceptual Design stage for the creation of passenger airplane families. The values of these reserves should be substantiated based on the evaluation of future functioning of the whole created airplane family within the airline fleet. This requires solving a problem of Pre-Design and requirements creation. Thus, the reserves become new design variables. The values of these new variables should be optimized together with the values of the existing “traditional” variables during airplane design. A model, which takes management of the aforementioned reserves into the account during airplane design, was constructed. The presented model is intended for usage within the framework of the models, which solve the problem of creation of a passenger airplane fleet at Pre-Design stage with taking the presence of an airplane family within this fleet into the account as well as optimization of this passenger airplane family. The model calculation results were verified for the trunk-route passenger airplanes of all main types with taking the existence of the appropriate families into the account. During verification the wing of each considered passenger airplane was sized for the appropriate family version with the maximum take-off weight. After that this wing was “fixed” and processed as initial data for the family version, statistics on which was used for checking the model calculation results. The verification demonstrated good correlation between the model calculation results and the available statistics. It also showed that the presented model can be used for the design of individual trunk-route passenger airplanes and families of all main types (short-, medium- and long-range).

1. Raymer, D.P. (2002). Enhancing aircraft conceptual design using multidisciplinary optimization: Doctoral Thesis. Stockholm: Royal Institute of Technology, 150 p.

2. Sheynin, V.M. & Makarov, V.M. (1982). [Role of modifications in the development of aircraft]. Moscow: Nauka, 226 p. (in Russian)

3. Stepanov, A.N. (1982). [Method of passenger airplanes design taking modification into account]. Moscow: MAI, 41 p. (in Russian)

4. Krauss, M. (1997). Variantenentwicklungen bei verkherflugzeugen: Doctoral Thesis. Munich: Technischen Universität München, 167 p. (in German)

5. Zhuravlev, P.V. (2014). Application of fleet creation problems in aircraft pre-design. Proceedings of the 29th Congress of the International Council of the Aeronautical Sciences, Saint-Petersburg. Available at: https://www.icas.org/ICAS_ARCHIVE/ICAS2014/data/papers/2014_0314_paper.pdf (accessed: 13.04.2022).

6. Zhuravlev, P.V. (2013). Analysis of significance of modifications and families for the design of modern passenger airplanes. Nauchnyy Vestnik MGTU GA, no. 188, pp. 121–125. (in Russian)

7. Zhuravlev, P. & Zhuravlev, V. (2012). Significance of modifications for development of passenger airplanes. Aircraft Engineering and Aerospace Technology, vol. 84, no. 3, pp. 172–180. DOI:10.1108/00022661211222021

8. Raymer, D.P. (2018). Aircraft design: A conceptual approach. 6th ed. Reston, VA, American Institute of Aeronautics and Astronautics Inc., 1062 p. DOI:10.2514/4.104909

9. Roskam, J. (1985). Airplane design. Part I: Preliminary sizing of airplanes. Ottawa: The University of Kansas, 207 p.

10. Torenbeek, E. (1982). Synthesis of subsonic airplane design. Delft University Press, Kluwer Academic Publishers, 598 p. DOI:10.1007/978-94-017-3202-4

11. Jenkinson, L.R., Simpkin, P. & Rhodes, D. (1999). Civil jet aircraft design. Civil jet aircraft design. London: Arnold, 1999. 418 p.

12. Nicolai, L.M. & Carichner, G.E. (2010). Fundamentals of aircraft and airship design. Vol. I – Aircraft design. Blacksburg, VA: American Institute of Aeronautics and Astronautics Inc., 907 p.

13. Eger, S.M., Mishin, V.F., Liseytsev, N.K. et al. (1983). [Airplane design], in Eger S.M. (Ed.). 3rd. ed., pererab. i dop. Moscow: Mashinostroyeniye, 616 p. (in Russian)

14. Brusov, V.S. & Baranov, S.K. (1989). [Optimal design of aircraft. Multi-purpose approach]. Moscow: Mashinostroyeniye, 232 p. (in Russian)

15. Arepyev, A.N. (1996). [Conceptual design of trunk-route passenger airplanes. Selection of configuration and parameters]. Moscow: MAI, 95 p. (in Russian)

16. Arepyev, A.N. (2012). [Guidelines for passenger airplanes design. Volume III. Definition of airplane and its parts parameters]. 4th ed. Moscow: MAI, 476 p. (in Russian)

17. Liseytsev, N.K. & Maksimovich, V.Z. (1990). [Calculation of take-off weight and selection of main airplane parameters]. Moscow: MAI, 52 p. (in Russian)

18. Kiselev, V.A. (1977). [Problems of layout and passenger airplanes configuration]. Moscow: MAI, 75 p. (in Russian)

19. Nita, M.F. (2013). Contributions to aircraft preliminary design and optimization: Doctoral Thesis. Bucharest, POLITEHNICA University of Bucharest, Hamburg, Hamburg University of Applied Sciences, 270 p. Available at: http://www.fzt.haw-hamburg.de/pers/Scholz/OPerA/NITA_DISS_A-C_Preliminary_Design_and_Optimization_2013.pdf (accessed: 13.04.2022).

20. Nita, M.F. & Scholz, D. (2012). Estimating the Oswald factor from basic aircraft geometrical parameters. German Aerospace Congress, German, Berlin, 10–12 September 2012. ID: 281424. Available at: https://www.fzt.haw-hamburg.de/pers/Scholz/OPerA/OPerA_PUB_DLRK_12-09-10.pdf (accessed: 13.04.2022).

21. Obert, E. (2008). Aerodynamic design of transport aircraft. Delft, Delft University Press, 638 p.

22. Obert, E. (2008). The role of aerodynamics in aircraft design and operation. Delft, Delft University Press, 904 p.

23. Skripnichenko, S.Yu. (2005). [Theoretical foundations of flight economy improvement]. Moscow: GoSNII GA, 368 p. (in Russian)

24. Pogosyan, M.A., Liseytsev, N.K., Strelets, D.Yu. et al. (2018). [Airplane design]. 5th ed., in Pogosyan M.A. (Ed.). Moscow: Innovatsionnoye Mashinostroyeniye, 864 p. (in Russian)

25. Airbus (2020). Airbus A320 Aircraft Characteristics Airport and Maintenance Planning. Blagnac: Airbus S.A.S., 388 p. Available at: https://www.airbus.com/sites/g/files/jlcbta136/files/2021-11/Airbus-Commercial-Aircraft-AC-A320.pdf (accessed 13.04.2022).