Superplastic pressure forming of a metal sheet into a long die with an isosceles trapezoid cross section

A.V. Gordienko; T.A. Beliakova

doi:10.48612/letters/2025-3-184-191

Superplastic pressure forming of a metal sheet into a long die with an isosceles trapezoid cross section

A.V. Gordienko

, T.A. Beliakova

показать трудоустройства и электронную почту

Получена 20 марта 2025; Принята 24 июля 2025;
Эта работа написана на английском языке

Цитирование: A.V. Gordienko, T.A. Beliakova. Superplastic pressure forming of a metal sheet into a long die with an isosceles trapezoid cross section. Письма о материалах. 2025. Т.15. №3. С.184-191

BibTex https://doi.org/10.48612/letters/2025-3-184-191

Аннотация

Forming scheme for a given pressure-time function. The colors on the right graph indicate different points of the shell.

Superplastic deformation of thin sheets is widely used in aerospace, automotive and other industries. In this paper, a mathematical model of plane strain superplastic pressure forming of a sheet specimen into a die is proposed. A die under consideration has a shape of a long box with an isosceles trapezoid cross section, but the model can be generalized for more complex die shapes. It is assumed that sticking happens between a shell and a die and thickness remains unchanged once contact occurs. The process of forming was divided into different phases, which are determined by the die geometry. For each phase, ordinary differential equations for thickness were derived along with the initial conditions. Solutions of obtained ODEs allow estimating the shell thickness at any point of a specimen as a function of coordinate along walls of the die and to determine the duration of each superplastic pressure forming phase for a given pressure-time function. Norton’s power law was used as a constitutive equation. Due to the simplicity of Norton`s law it is possible to solve some of ODEs analytically. The proposed model can be used with other types of constitutive relations, in particular with relations that include microstructure parameters etc. The superplastic forming of a Ti-6Al-4V titanium alloy sheet for the piecewise pressure-time function has been modelled. Some special cases of die geometry are analyzed.

Ссылки (34)

1. K. A. Padmanabhan, R. A. Vasin, F. U. Enikeev, Superplastic Flow: Phenomenology and mechanics, Berlin-Heidelberg: Springer-Verlag, Berlin, 2001, 363 p

2. R. A. Vasin, F. U. Enikeev, Introduction to the mechanics of superplasticity. Part I, Gilem, Ufa, 2001, 280 p. (in Russian) [Р. А. Васин, Ф. У. Еникеев, Введение в механику сверхпластичности. Т1, Гилем, Уфа, 2001, 280 с.].

3. N. N. Malinin, Creep in metal working, Mashinostroenie, Moscow, 1986, 222 p. (in Russian) [Н. Н. Малинин, Ползучесть в обработке металлов, Машиностроение, Москва, 1986, 222 с.].

4. D. Sorgente, Superplasticity and Superplastic Forming, Metals 11 (2021) 946

5. F. Jovane, An approximate analysis of the superplastic forming of a thin circular diaphragm: Theory and experiments, International Journal of Mechanical Sciences 10, 5 (1968) 403 - 427

6. N. Chandra, D. Kannan, Superplastic sheet metal forming of a generalized cup. Part I: Uniform thinning, JMEP 1 (1992) 801- 810

7. N. Chandra, D. Kannan, Superplastic sheet metal forming of a generalized cup. Part II: Nonuniform thinning, JMEP 1 (1992) 813 - 822

8. A. A. Kruglov, V. R. Ganieva, O. P. Tulupova, F. U. Enikeev, Methods to calculate the time of thin circular membrane superplastic forming, Izv. VUZ, Tsvet. Met. 2 (2017) 66 - 75. (in Russian) [А. А. Круглов, В. Р. Ганиева, О. П. Тулупова, Ф. У. Еникеев, Методы расчета продолжительности сверхпластической формовки круглой мембраны, Изв. ВУЗов, Цвет. Мет. 2 (2017) 66 - 75.]

9. D. L. Holt, An analysis of the bulging of a superplastic sheet by lateral pressure, Int. Journal of Mech. Sci. 12, 6 (1970) 491- 497

10. P. Guglielmi, D. Sorgente, A. Lombardi, G. Palumbo, A new experimental approach for modelling the constitutive behaviour of sheet metals at elevated temperature through interrupted bulge tests, Int. Journal of Mech. Sci. 184 (2020) 105839

11. T. A. Beliakova, I. A. Goncharov, The effect of metal alloy microstructure on the thickness distribution in the circular plate under the superplastic blow-forming, Vestn. of SamU, Natural Sci. Ser. 26, 2 (2020) 50 - 62. (in Russian) [Т. А. Белякова, И. А. Гончаров, Влияние микроструктуры металлического сплава на распределение толщины в круглой пластине при сверхпластической формовке давлением, Вестн. СамУ, Естественнонаучн. сер. 26, 2 (2020) 50 - 62.]

12. L. García-Barrachina, D. Sorgente, L. Tricarico, A. J. Gámez, A method for estimating superplastic material parameters via free-inflation tests, JMRT 11 (2021) 1387 -1395

13. R. V. Safiullin, V. A. Valitov, R. Y. Lutfullin, E. V. Galieva, E. Y. Klassman, Superplastic forming of EK61 nickel-based superalloy with ultrafine-grained structure, Lett. Mater. 12, 4s (2022) 439 - 444

14. M. R. Shagiev, A. A. Kruglov, O. A. Rudenko, M. A. Murzinova, Superplastic forming of titanium alloys at 700°C, Lett. Mater. 12, 4 (2022) 332 - 335

15. G. R. Murzina, V. R. Ganieva, A. A. Kruglov, F. U. Enikeev, Modeling of the process of superplastic forming of hemispherical shells from blanks of different profiles, Lett. Mater. 11, 4s (2021) 548 - 552

16. G. R. Murzina, V. R. Ganieva, F. U. Enikeev, O. P. Tulupova, Software for calculating technological and geometric characteristics of the superplastic forming process, Int. Journal of Open Inf. Tech. 12, 11 (2024) 35 - 40. (in Russian) [Г. Р. Мурзина, В. Р. Ганиева, Ф. У. Еникеев, О. П. Тулупова, Программное средство для расчета технологических и геометрических характеристик процесса сверхпластической формовки, Int. Journal of Open Inf. Tech. 12, 11 (2024) 35 - 40.].

17. I. Zakhariev, Numerical simulation of superplastic bulge forming test, J. Phys.: Conf. Ser. 1740 (2021) 012021

18. O. Tulupova, C. Gumerova, V. Ganieva, A. Kruglov, F. Enikeev, Improving the accuracy of finite element modeling of superplastic forming processes, Lett. Mater. 12, 2 (2022) 142 -147

19. A. A. Kruglov, O. P. Tulupova, N. V. Olimpieva, V. R. Ganieva, F. U. Enikeev, Superplastic forming of hemispheres out of AZ61 magnesium alloy, IOP Conference Series: Mat. Sci. and Engineering, Ufa, 1008 (2020) 012050

20. A. R. Ragab, Thermoforming of superplastic sheet in shaped dies, Metals Technology 10, 1 (1983) 340 - 348

21. R. A. Vasin, F. U. Enikeev, R. V. Safiullin, Mathematical Modeling of Superplastic Forming of a Long Rectangular Box Section, Mater. Sci. Forum 304 - 306 (1999) 765 - 770

22. R. A. Vasin, F. U. Enikeev, M. Tokuda, R. V. Safiullin, Mathematical modelling of the superplastic forming of a long rectangular sheet, Int. Journal of Non-Linear Mech. 38 (2003) 799 - 807

23. N. Chandra, K. Chandy, Superplastic process modeling of plane strain components with complex shapes, J. Mat. Shaping Technology 9 (1991) 27 - 37

24. L. Carrino, G. Giuliano, Analysis of Superplastic Testing by Using Constant Pressure in Prismatic Die, MSF 357 - 359 (2001) 219 - 224

25. A. Kh. Akhunova, S. V. Dmitriev, A. A. Kruglov, R. V. Safiullin, Superplastic forming of sheet into wedge die, Russian metallurgy (Metally) (2010) 9 38 - 41.

26. G. R. Murzina, A. R. Zharmukhametova, V. R. Ganieva, F. U. Enikeev, Method for calculating the parameters of superplasticity of titanium alloys based on the results of test forming into a rectangular matrix at constant pressure, Bulletin of the south Ural state university, 16, 1 (2023) 96 -107

27. A. R. Goronkova, F. U. Enikeev, A. A. Kruglov, Perzyna's model use for the modeling processes of superplastic forming of rectangular membranes, Kuznechno-shtampovochnoe proizvodstvo, Obrabotka materialov davleniem 9 (2016) 11-18. (in Russian) [А. Р. Горонкова, Ф. У. Еникеев, А. А. Круглов, Применение модели Пэжины для моделирования процесса сверхпластической формовки прямоугольной мембраны, Кузнечно-штамповочное производство, Обработка материалов давлением 9 (2016) 11-18.].

28. A. A. Kruglov, F. U. Enikeev, Finite element modeling of the process of superplastic forming of a rectangular membrane, Kuznechno-shtampovochnoe proizvodstvo, Obrabotka materialov davleniem 2 (2019) 31 - 40. (in Russian) [А. А. Круглов, Ф. У. Еникеев, Конечноэлементное моделирование процесса сверхпластической формовки прямоугольной мембраны, Кузнечно-штамповочное производство, Обработка материалов давлением 2 (2019) 31- 40.].

29. F. S. Jarrar, M. A. Nazzal, Inclination Angle Effect on the Thickness Distribution in a Superplastic Formed Long Rectangular Pan, MSF 735 (2012) 155 -161

30. R. Trân, F. Reuther, S. Winter, V. Psyk, Process Development for a Superplastic Hot Tube Gas Forming Process of Titanium (Ti-3Al-2.5V) Hollow Profiles, Metals 10 (2020) 1150

31. M. N. Postnikova, A. D. Kotov, A. I. Bazlov, A. O. Mosleh, S. V. Medvedeva, A. V. Mikhaylovskaya, Effect of Boron on the Microstructure, Superplastic Behavior, and Mechanical Properties of Ti-4Al-3Mo-1V Alloy, Materials 16 (2023) 3714

32. A. D. Kotov, M. N. Postnikova, A. O. Mosleh, A. V. Mikhaylovskaya, Effect of Co addition on the microstructure evolution and superplastic behavior of Ti-4Al-3Mo-1V-0.1B alloy, Materials Research Proceedings 32 (2023) 181-188

33. N. Tian, X. Song, W. Ye, S. Hui, Superplastic Deformation Behavior of A β-rich α+β Titanium Alloy, JMRT 25 (2023) 1150 -1163

34. Y. Mi, Y. Lu, D. Wang, Y. Zhao, Y. Dong, H. Chang, I. V. Alexandrov, A Study of the Superplastic Deformation Behavior of Low-Cost Ti-2Fe-0.1B Alloys, Materials 17 (2024) 1282

Финансирование на английском языке

1. Interdisciplinary Scientific and Educational School of Moscow University "Fundamental and Applied Space Research" - 23-Ш01-01

Superplastic pressure forming of a metal sheet into a long die with an isosceles trapezoid cross section

Аннотация

Ссылки (34)

Финансирование на английском языке

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