Numerical evaluation of crack resistance of welded compositions made of titanium sheets manufactured in the superplasticity mode

numerical assessment of the crack resistance of titanium alloy sheet blanks with various microstructures connected by pressure welding in the superplasticity mode is considered. The structural and mechanical model of the object under consideration is represented as a graph.
Based on functional averaging, an iterative method for finding stress and strain parameters for its vertices is implemented as a generalization of Newton’s method. The presented results of
a mathematical analysis of the mechanics of the origin and development of cracks in a twolayer welded billet made of VT6 titanium alloy with a fundamentally different microstructure
indicate the prospects of using such layered titanium compositions in critical products in order to increase their structural strength.

1. Malysheva, S.P., Myrsinova, M. A., Jerebcov, C. V., Salyschev, G. A. 2011, “Mechanical properties of ultrafine-grained titanium alloy VT6”, Perspectivnye materialy, no. 12, pp. 316– 320.

2. Sarkeeva, A. A., Lutfullin, R.Ya., Kruglov, A. A, Astanin, V. V. 2012, “Influence of the structure jn the mechanical behavior jf VT6 titanium alloy under impact loading”, Letters on materials, no. 2, pp. 99–102.

3. Valiev, R. Z., Klevtsov, G. V., Semenova, I.P. and other. 2012, “Strength and mechanism of impact fracture of titanium and its alloys in the initial and submicrocrystalline states”, Deformatsiya i Razrushenie materialov no. 11, pp. 32–37.

4. Salischev, G. A., Jerebtcov, S.V., Malysheva, S.P. and other. 2009, “The use of titanium alloys with a submicrocrystalline structure for the manufacture of parts aircraft engines”, Perspectivnye materialy, no. 7, pp. 280–285.

5. Sarkeeva, A. A., Kruglov, A. A., Borodin, E.M and other. 2012, “Impact loading behavior of titanium alloy laminated material”, Physical mesomechanics, no 5, pp. 51–57.

6. Sarkeeva, A. A. 2022, “Impact fracture characteristics of multilayer laminate based on nearalpha titanium alloy”, Letters on materials, no. 12(4s), pp. 499–503.

7. Valiachmetov, O. R., Galeev, R. M., Ivanko, V. A., and other. 2010, “Using nanostructured materials and nanotechnology to create hollow structures”, Russian nanotechnology, no. 12(4s), Vol.5. no 1-2, pp. 102–111.

8. Sarkeeva, A. A. & Kruglov, A. A. 2022, “Characteristics of the mechanical behavior of a nearalpha multilayer laminate under impact loading”, Letters on materials, no. 13(4s), pp. 488–492.

9. Zverev, G. N. 2023, “Principles, bases, laws of fundamental computer science”, Open education, no 3, pp. 4–11.

10. Reiner, M. 1965, Rheology, Nauka, Moscow, Russia 223 pp.

11. Smirnov, O. M. 1979, Pressure treatment of metals in a state of superplasticity, Mashinostroenie, Moscow, Russia.

12. Parton, V. Z. 1990, Elementary engine, Fismatlit, Moscow, Russia.

13. Broek, D. 1980, Elementary engineering fracture mechanics, Vishsaya Shkola, Moscow, Russia.

14. Sachkov, V.V. 1989, Elementary engineering fracture mechanics, Nauka, Moscow, Russia.

15. Barykin, N.P. & Galimov, A. K. 1999, “Structural and mechanical models of materials in conditions of pressure treatment and subsequent operation”, Forging and stamping production. Material working by pressure, no 4, pp. 4–8.