The problem of T-shaped junction of two thin Timoshenko inclusions in a two-dimensional elastic body

We consider the equilibrium problem for a two-dimensional elastic body containing two contacting thin inclusions of a rectilinear shape. The inclusions are elastic and are modeled within the framework of the theory of Timoshenko beams. The inclusions intersect at a right angle, and one of the inclusions delaminates from the elastic matrix, forming a crack. The problem is posed as a variational one and a complete differential formulation is obtained in the form of a boundary value problem, including junction conditions at a common point of inclusions. On the edges of the cut, boundary conditions of the form of inequalities are specified. The equivalence of the variational and differential formulations of the problem is proved under the condition of sufficient smoothness of the solutions. The passage to the limit with respect to the stiffness parameter of one of the inclusions is substantiated.

1. Sanchez-Palencia E., Nonhomogeneous Media and Vibration Theory, Springer, New York (1980).

2. Itou H. and Khludnev A. M., “On delaminated thin Timoshenko inclusions inside elastic bodies,” Math. Meth. Appl. Sci., 39, 4980–4993 (2016).

3. Khludnev A. M. and Leugering G. R., “On Timoshenko thin elastic inclusions inside elastic bodies,” Math. Mech. Solids, 20, No. 5, 495–511 (2015).

4. Shcherbakov V. V., “The Griffith formula and J-integral for elastic bodies with Timoshenko inclusions,” Z. Angew. Math. Mech., 96, No. 11, 1306–1317 (2016).

5. Nikolaeva N. A., “On equilibrium of the elastic bodies with cracks crossing thin inclusions,” J. Appl. Ind. Math., 13, 685–697 (2019).

6. Khludnev A. M. and Popova T. S., “Timoshenko inclusions in elastic bodies crossing an external boundary at zero angle,” Acta Mech. Solida Sin., 30, No. 3, 327–333 (2017).

7. Khludnev A. M., Faella L., and Popova T. S., “Junction problem for rigid and Timoshenko elastic inclusions in elastic bodies,” Math. Mech. Solids, 22, No. 4, 737–750 (2017).

8. Khludnev A. M. and Popova T. S., “On junction problem for elastic Timoshenko inclusion and semi-rigid inclusion [in Russian],” Mat. Zametki SVFU, 25, No. 1, 73–89 (2018).

9. Khludnev A. M. and Popova T. S., “Equilibrium problem for elastic body with delaminated T-shape inclusion,” J. Comput. Appl. Math., 376, article 112870 (2020).

10. Khludnev A. M., “T-shape inclusion in elastic body with a damage parameter,” J. Comput. Appl. Math., 393, article 113540 (2021).

11. Neustroeva N. V. and Lazarev N. P., “Junction problem for Euler–Bernoulli and Timoshenko elastic beams [in Russian],” Sib. Electron. Math. Rep., 13, 26–37 (2016).

12. Bogan Yu. А., “Homogenization of a nonhomogeneous elastic beam with elements joined by a hinge of finite stiffness [in Russian],” Sib. Zh. Ind. Mat., 1, No. 2, 67–72 (1998).

13. Leugering G., Nazarov S. A., and Slutskij A. S., “The asymptotic analysis of a junction of two elastic beams,” Z. Angew. Math. Mech., 99, paper No. e201700192 (2019).

14. Leugering G., Nazarov S. A., Slutskij A. S., and Taskinen J., “Asymptotic analysis of a bit brace shaped junction of thin rods,” Z. Angew. Math. Mech., 100, paper No. 201900227 (2020).

15. Caddemi S., Calio I., and Cannizzaro F., “The influence of multiple cracks on tensile and compressive buckling of shear deformable beams,” Int. J. Solids Structures, 50, No. 20–21, 3166–3183 (2013).

16. Palmeri A. and Cicirello A., “Physically-based Dirac’s delta-functions in the static analysis of multi-cracked Euler–Bernoulli and Timoshenko beams,” Int. J. Solids Structures, 48, No. 14–15, 2184–2195 (2011).

17. Khludnev A. M., Problems of Elasticity Theory in Nonsmooth Domains [in Russian], Fizmatlit, Moscow (2010).

18. Lions J. L., Quelques M´ethodes de R´esolution des Probl´emes aux Limites non Lin´eaires, Dunod, Paris (1969).

19. Khludnev A. M. and Kovtunenko V. A., Analysis of Cracks in Solids, Southampton; Boston, WIT Press (2000).

20. Itou H., Kovtunenko V. A., and Rajagopal K. R., “Crack problem within the context of implicitly constituted quasi-linear viscoelasticity,” Math. Models Methods Appl. Sci., 29, No. 2, 355–372 (2019).

21. Itou H., Kovtunenko V. A., and Rajagopal K. R. , “On the states of stress and strain adjacent to a crack in a strain-limiting viscoelastic body,” Math. Mech. Solids, 23, 433–444 (2018).

22. Popova T. S., “The problem of equilibrium of a viscoelastic body with a thin rigid inclusion [in Russian],” Mat. Zametki SVFU, 21, No. 1, 47–55 (2014).

23. Popova T. S., “Problems of thin inclusions in a two-dimensional viscoelastic body,” J. Appl. Ind. Math., 12, 313–324 (2018).

24. Rudoy E. M. and Lazarev N. P., “Domain decomposition technique for a model of an elastic body reinforced by a Timoshenko’s beam,” J. Comput. Appl. Math., 334, 18–26 (2018).

25. Khludnev A. M. and Leugering G., “On elastic bodies with thin rigid inclusions and cracks,” Math. Methods Appl. Sci., 33, No. 16, 1955–1967 (2010).

26. Lazarev N. P., Popova T. S., and Rogerson G. A., “Optimal control of the radius of a rigid circular inclusion in inhomogeneous two-dimensional bodies with cracks,” Z. Angew. Math. Phys., 69, paper No. 53 (2018).

27. Rudoy E. M., “Numerical solution of an equilibrium problem for an elastic body with a delaminated thin rigid inclusion [in Russian],” Sib. Zh. Ind. Mat., 19, No. 2, 74–87 (2016).

28. Alexandrov V. M., Smetanin B. I., and Sobol B. V., Thin Stress Concentrators in Elastic Bodies [in Russian], Fizmatlit, Moscow (1993).

29. Goudarzi M., Dal Corso F., Bigoni D., and Simone A., “Dispersion of rigid line inclusions as stiffeners and shear band instability triggers,” Int. J. Solids Structures, 210–211, 255–272 (2021).

30. Ciarlet P., Mathematical Elasticity: Theory of Plates, Amsterdam, Elsevier (1997).

31. Gaudiello A., Monneau R., Mossino J., Murat F., and Sili A., “On the junction of elastic plates and beams,” C. R., Math., 335, 717–722 (2002).

32. Titeux I. and Sanchez-Palencia E., “Junction of thin plates,” Eur. J. Mech., A, Solids, 19, No. 3, 377–400 (2000).

33. Gruais I., “Modeling of the junction between a plate and a rod in nonlinear elasticity,” Asymptotic Anal., 7, 179–194 (1993).