Prefracture model of a layer with a hole based on the interaction arc concept

For an elastic symmetric body in the form of a layer weakened by a hole and loaded in mode 1, the concept of an interaction arc (IA) is introduced. The IA forms a small neighborhood of the point of maximum specific free energy in the middle section of the layer. The free energy flow through IA is represented by the energy product (EP) - the product of the specific free energy and a linear parameter. Using the well-known asymptotic expressions for the stress field in the neighborhood of the hole apex, a relationship is obtained between the linear parameter and the radius of curvature of the hole apex, which ensures the independence of the EP from the radius of curvature and the linear parameter. When the radius of curvature is zero, the
hole degenerates into a mathematical cut. In this case, the EP is reduced to the Irwin formula.
Thus, if any hole degenerates into a mathematical cut, then regardless of the geometry of the cut edges, in the limit, we must come to the same stress intensity factor (SIF). In particular, we use a semi-elliptical hole. A technique for determining the SIF-1 is proposed, based on the
representation of the approximating SIF in terms of dimensionless free energy flows that take a stationary value as the radius of curvature tends to zero. The values of the SIF obtained by this method coincide with their values given in other sources based on the analysis of the disclosure of the mathematical cut. In particular, a rectangular layer subjected to a distributed load is considered. The solutions were obtained by the FEM using the CAE Fidesys software package.
The difference with the known results was less than one percent.

1. Irwin, G. R 1948, “Fracture dynamics”, Fracturing of Metals. American Society for Metals, Cleveland, pp. 147-166.

2. Griffith A.A. 1920, “The phenomenon of rupture and flow in solids”, Phil. Trans. Roy. Soc, A221, pp. 163-198.

3. Vainshtok V.A. & Kravets P.Y. 1990, “Calculation of the stress intensity factors and nominal stresses in the plane of a crack from the opening of its edges”, Strength of Materials, vol. 22, pp. 807–815. doi: 10.1007/BF00767438

4. Gudkov N.A. & Chernyatin A.S. 2018, “Computing parameters of fracture mechanics based on a heuristic approach to determining the location of the crack тip”, Vestnik MGTU im. N.E. Baumana, vol. 2 (119), pp. 4-16. doi: 10.18698/0236-3941-2018-2-4-16

5. Dilman V.L. & Utkin P.B. 2022, “Two-parameter method of determinining stress intensity factor KI of crack-like defects using holographic interferometry”, Vestn. Yuzhno-Ural. Gos. Un-ta. Ser. Matem. Mekh. Fiz., vol. 14, issue 3, pp. 60–67. doi: 10.14529/mmph220307

6. Zakharov A.P., Shlyannikov V.N. & Ishtyryakov I.S. 2019, “Plastic stress intensity factor in fracture mechanics”, PNRPU Mechanics Bulletin, 2019, no. 2, pp. 100-115. doi: 10.15593/perm.mech/2019.2.08

7. Miyazaki N., Ikeda T. & Munakata T. 1989, “Analysis of stress intensity factor using the energy method combined with the boundary element method”, Computers and Structures, vol. 33, issue 3, pp. 867-871. doi: 10.1016/0045-7949(89)90261-7

8. Hellen T.K. & Blackburn W.S. 1975, “The calculation of stress intensity factors for combined tensile and shear loading”, International Journal of Fracture, vol. 11, pp. 605–617. doi:10.1007/BF00116368

9. Diaz F., Patterson E. & Yates J. 2009, “Assessment of effective stress intensity factors using thermoelastic stress analysis”, Journal of Strain Analysis for Engineering Design, vol. 44, pp. 621-632. doi: 10.1243/03093247JSA515

10. Chandra R. 1989, “Experimental determination of stress intensity factors in patched cracked plates”, Engineering Fracture Mechanics, vol. 33, issue 1, p. 65-79. doi: 10.1016/0013-7944(89)90055-6

11. Cerniglia D., Nigrelli V. & Pasta A. 1999, “Experimental and numerical determination of stress intensity factor in composite materials”, Proceedings of the 1999 Internatoinal Conference on Composite Materials, pp. 1-8.

12. Lopez-Crespo P. 2008, “The stress intensity of mixed mode cracks determined by digital image correlation”, The Journal of Strain Analysis for Engineering Design, vol. 43, no. 8, p. 769-780. doi: 10.1243/03093247JSA419

13. Camacho Reyes A., Vasco-Olmo J.M., Lopez-Alba E., Felipe-Sese L., Molina-Viedma A. J., Almazan-Lazano J. A. & Diaz F. 2022, “Evaluation of the effective stress intensity factor using thermoelastic stress analysis and 2D digital image correlation”, The 19th International Conference on Experimental Mechanics, pp. 1-7. doi: 10.3390/psf2022004027

14. Glagolev, V.V. & Markin, A.A. 2019, “Fracture models for solid bodies, based on a linear scale parameter”, Int. J. Solids and Struct, vol. 158, pp. 141-149. doi: 10.1016/j.ijsolstr.2018.09.002

15. Berto F., Glagolev V.V., Glagolev L.V. & Markin A.A. 2020 “Modelling shear loading of a cantilever with a crack-like defect explicitly including linear parameters”, International Journal of Solids and Structures, vol. 193-194, pp. 447–454. doi: 10.1016/j.ijsolstr.2020.02.039

16. Berto F., Glagolev V.V. & Markin A.A. “A body failure model with a notch based on the scalable linear parameter”, PNRPU Mechanics Bulletin, no. 4, pp. 93–97. doi:10.15593/perm.mech/2018.4.08

17. Creager M. 1966, “The elastic stress field near the tip of a blunt crack”, Masters thesis, Lehigh University, p. 40.

18. Murakami Yu. 1990, “Spravochnik po koeffitsiyentam intensivnosti napryazheniy v 2-kh tomakh. Tom 2.” ,Handbook of stress intensity factors in 2 volumes. Vol. 2, Moscow: Mir, p. 568.