Optimization of a radial-axial turbine at the stage of center line of fluid flow calculation

Introduction (problem statement and relevance). There is some significant potential for radialaxial turbine efficiency increase at the initial design stage, namely the center line of fluid flow calculation, due to the fact that the impeller machine appearance is formed and its main shape and dimensions are determined at this stage. Traditional approaches to optimization of a radial-axial turbine at the stage of center line of fluid flow calculation assume introduction of auxiliary variables or simplification of the initial system of equations.

The purpose of the study is to develop a numerical algorithm for searching optimal parameters of a radial-axial turbine at the stage of center line of fluid flow calculation using numerical optimization methods; comparison of the results obtained using the numerical algorithm with the results of optimization performed on the basis of traditional approaches.

Methodology and research methods. Formalization of radial-axial turbine center line of fluid flow calculation in the form of a nonlinear programming problem. Solving the nonlinear programming problem using numerical optimization methods.

Scientific novelty and results. Constrained nonlinear optimization of parameters of a radial-axial turbine at the stage of center line of fluid flow calculation and its subsequent software implementation.

Practical significance. Improving accuracy and reducing time of search for the optimal solution at the stage of radial-axial turbine center line of fluid flow calculation.

1. Mitrokhin V.T. [Selection of parameters and calculation of a centripetal turbine in stationary and transient modes]. Moscow, Mashinostroenie Publ., 1974. 227 p. (In Russian)

2. Sherstyuk A.N., Zaryankin A.E. [Low power radialaxial turbines]. Moscow, Mashinostroenie Publ., 1976. 208 p. (In Russian)

3. Passar A.V., Timoshenko D.V. [Study of the influence of the degree of radiality on the flow structure in the flow part of a radial-axial turbine of a gas turbine installation]. Izvestiya Tomskogo politekhnicheskogo universiteta, 2017, no. 5, pp. 24–38. (In Russian)

4. Passar A.P., Komyalova E.V. [Modelling of current in the setting of the radial-axial turbine of the compounedengine]. Informatika i sistemy upravleniya, 2017, no. 4 (54), pp. 62–73. (In Russian)

5. Kartashev A.L., Martynov A.A. [Mathematical modeling and optimization of flow structure in francis turbine stage of microturbine power plant]. Vestnik Yuzhno-Ural’skogo gosudarstvennogo universiteta, 2015, no. 3 (15), pp. 28–36. (In Russian)

6. Zhang J., Zangeneh M. Multidisciplinary and multipoint optimization of radial and mixed-inflow turbines for turbochargers using 3D inverse design method. 14th International Conference on Turbochargers and Turbocharging, 2020, pp. 263–277.

7. Yun J., Atac O., Kim J. Influence of trailing edge curve on the performance of radial turbine in turbocharger. International Journal of Low-Carbon Technologies, 2023, vol. 18, pp. 570–579.

8. Ebel T. Does meanline design still make sense in the Era of CFD and optimization. Available at: https://www.conceptsnrec.com/blog/does-meanline-design-stillmake-sense-in-the-era-of-cfd-and-optimization (accessed 11 June 2023).

9. Kuz’michev V.S., Tkachenko A.Yu., Filinov E.P. [The efficiency limits of the traditional gas turbine engines]. Vestnik UGATU, 2017, vol. 21, no. 1 (75), pp. 91– 99. (In Russian)

10. Tkachenko A.Yu., Filinov E.P., Kuz’michev V.S. [Optimization of operating process parameters and choice of schemes of small-sized two-circuit turbojet engines for various aircraft]. Vestnik UGATU, 2021, vol. 25, no. 1 (95), pp. 58–64. (In Russian)

11. Tkachenko A.Yu., Filinov E.P., Ostapyuk Ya.A. [Gas turbine engine optimization at conceptual designing]. Vestnik UGATU, 2018, vol. 22, no. 2 (80), pp. 64–72. (In Russian)

12. Passar A.V., Lashko V.A. [Analytical review of methods for calculating turbines at medium radius]. Spravochnik. Inzhenernyy zhurnal, 2013, no. 9, pp. 2–12. (In Russian)

13. Nosov M.V. [Calculation of the main parameters of a single-stage centripetal turbine]. Moscow, 1961. 85 p. (In Russian)

14. Epifanova V.I. [Low temperature radial turboexpanders]. Moscow, Mashgiz Publ., 1961. 446 p. (In Russian)

15. Zaydel’ R.R. [Turboexpanders for oxygen units]. Moscow, Mashgiz Publ., 1960. 176 p. (In Russian)

16. Prikhod’ko M.S. [On the issue of optimal operating conditions for a centripetal turbine stage]. Trudy LKI, 1961, issue 34. (In Russian)

17. Baykov B.P., Bordukov V.G., Ivanov P.V. [Turbochargers for supercharging diesel engines. Reference Guide]. Leningrad, Mashinostroenie Publ., 1975. 199 p. (In Russian)

18. Bogdanova E.L., Soloveychik K.A., Arkina K.G. [Optimization in project management: nonlinear programming: tutorial]. Saint Petersburg, Universitet ITMO Publ., 2017. 190 p. (In Russian)

19. Karpyuk I.A., Kulyashova N.M., Shiryaev V.D. [Operations Research: A Study Guide]. Saransk, Mordovskiy universitet Publ., 2018. 110 p. (In Russian)

20. Sablinskiy A.I. [Methods of optimal solutions: instructions for completing tests in the discipline]. Kemerovo, Kemerovskiy tekhnologicheskiy institut pishchevoy promyshlennosti Publ., 2012. 96 p. (In Russian)

21. Gol’dshteyn A.L. [Optimization in MATLAB: tutorial]. Perm, Permskiy natsional’nyy issledovatel’skiy politekhnicheskiy universitet Publ., 2015. 192 p. (In Russian)

22. Byrd R.H. et al. On the local behavior of an interiorpoint algorithm for nonlinear programming. Reading, UK, Addison Wesley Longman, 1997.

23. Constrained Nonlinear Optimization Algorithms. Available at: https://www.mathworks.com/help/optim/ug/constrained-nonlinear-optimization-algorithms.html#brnox01 (accessed 02 March 2024).

24. Genetic Algorithm. Available at: https://www.mathworks.com/discovery/genetic-algorithm.html (accessed 02 March 2024).

25. Martynov A.A., Mashkov O.G., Shestakov D.S. [Creation of a high-pressure supercharging unit for the DM185 family of diesel engines as part of import substitution]. Dvigatel’, 2023, no. 1-3, pp. 20–24. (In Russian)