In the industrial field, the control of the structural integrity of a cracked metal part remains a capital maneuver in the prediction of failures in order to accurately define the functional lifetime of these parts. In this case, the Stress Intensity Factor (SIF) plays a central role to assess the damaging of a crack in a structure under a given loading. The purpose of this paper is to examine and check the analytical calculation of the SIF through an empirical approach of the form factor with those computing in mode I, using in the linear elastic domain, by the finite element method with ABAQUS software for two different cracked sections. The first defect studied in this work has a form of a circular section with a central crack under uniform tensile load. The second defect has a form of elliptical section with a central crack under uniform tensile load. The form factor function Y used, remains the main element for the analytical stress intensity factor determination. For each form of section, the obtained results were examined by comparing with the results given by the ABAQUS software. Indeed, after examination, the model was finally approved and validated for the circular section, on the other hand, it couldn’t be validated and adopted unfortunately in the elliptical case.
| [1] | Collins, J. A., Busby, H. R., & Staab, G. H. (2009). Mechanical design of machine elements and machines: a failure prevention perspective. John Wiley & Sons. |
| [2] | Rice, J. R., & Tracey, D. M. (1969). On the ductile enlargement of voids in triaxial stress fields∗. Journal of the Mechanics and Physics of Solids, 17(3), 201-217.View Article |
| [3] | Gurson, A. L. (1977). Continuum theory of ductile rupture by void nucleation and growth: Part I—Yield criteria and flow rules for porous ductile media.View Article |
| [4] | Sih, G. C., & Macdonald, B. (1974). Fracture mechanics applied to engineering problems-strain energy density fracture criterion. Engineering Fracture Mechanics, 6(2), 361-386.View Article |
| [5] | Mecholsky Jr, J. J. (1995). Fracture mechanics principles. Dental Materials, 11(2), 111-112.View Article |
| [6] | Olson, J. E. (1991). Fracture mechanics analysis of joints and veins (Doctoral dissertation, Stanford University). |
| [7] | IRWIN G.R.: “Fracture dynamics “, Fracturing of metals ASM Publi., (1948), pp.b147-166. |
| [8] | Paris, P. C., & Sih, G. C. (1965). Stress analysis of cracks. ASTM stp, 381, 30-81.View Article |
| [9] | Gdoutos, E. E. (2020). Fracture mechanics: an introduction (Vol. 263). Springer Nature.View Article |
| [10] | Irwin, G. R. (1957). Analysis of stress and strains near the end of a crack traversing a plate, Applied Mechanics.View Article |
| [11] | Chan, S. K., Tuba, I. S., & Wilson, W. K. (1970). On the finite element method in linear fracture mechanics. Engineering fracture mechanics, 2(1), 1-17.View Article |
| [12] | Rice, J. R. (1968). A path independent integral and the approximate analysis of strain concentration by notches and cracks.View Article |
| [13] | Systèmes, D. (2007). Abaqus analysis user’s manual. Simulia Corp. Providence, RI, USA, 40. |
| [14] | Zehnder, A. T. (2007). Lecture notes on fracture mechanics. Cornell University, 20, 22. |
| [15] | Adamson, R. M., Dempsey, J. P., & Mulmule, S. V. (1996). Fracture analysis of semi-circular and semi-circular-bend geometries. International Journal of Fracture, 77(3), 213-222.View Article |
| [16] | Tada, H., Paris, P. C., & Irwin, G. R. (1973). The stress analysis of cracks. Handbook, Del Research Corporation, 34. |
