This paper presents numerical study on the stress intensity factors (SIF) for slanted surface crack subjected to mode I loading. Tremendous amount of works can be found in discussing the normal crack under various types of loadings. According to literature survey, there is no significant information on the SIFs for slanted cracks available. Therefore, the purpose of this paper is to develop the slanted numerical crack model using ANSYS finite element program and to analyze the behavior of various type of geometries of slanted cracks. Since no SIFs for slanted cracks are available, then the present model is compared with the previous normal crack for the validation purposes. It is found that the present model is well agreed with the existing model. Several important parameters are used; crack aspect ratio, a/b, relative crack depth, a/D and slanted angle, . It is realized that such parameters played important roles in determining the SIFs where if a/b and a/D are increased, the SIFs are also increased. When the slanted angles are introduced, the SIFs decreased when compared with the normal cracks. Instead of mode I SIF, mode II are also induced and therefore affecting the structural reliability. However, mode II SIF is relatively insignificant compared with mode I SIF
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A. E. Ismail, A. K. Ariffin, S. Abdullah and M. J. Ghazali, Off-set Crack Propagation Analysis under Mixed Mode Loadings, International Journal of Automotive Technology, Vol. 12, n. 2, pp. 225-232, 2011.

S. Raju and J. C. Newman, Fracture Mechanics, ASTM Special Technical Publication, Vol. 905, n. 17, pp. 789–805, 1986.

J. Toribio, J. C. Matos and B. Gonzalez, Numerical Modelling of Crack Shape Evolution for Surface Flaws in Round Bars under Tension Loadings, Engineering Failure Analysis, Vol. 16, n. 2, pp. 618–630, 2009.

Y. Murakami and H. Tsuru, Stress intensity factor handbook. Pergamon, New York, 1986.

A. Carpinteri, Elliptical-arc Surface Cracks in Round Bars, Fracture of Engineering Materials and Structures, Vol. 15, n. 11, pp. 1141–1153, 1999.

C. S. Shin and C. Q. Cai, Experimental and Finite Element Analyses on Stress Intensity Factors of an Elliptical Surface Crack in a Circular Shaft under Tension and Bending, International Journal of Fatigue, Vol. 129, n. 3, pp. 239–264, 2004.

M. D. Fonte and M. D. Freitas, Stress Intensity Factors for Semi-elliptical Surface Cracks in Round Bars under Bending and Torsion, International Journal of Fatigue, 21 (5), 457-463, 1999.

A. E. Ismail, A. K. Ariffin, S. Abdullah and M. J. Ghazali, Stress Intensity Factors for Surface Cracks in Round Bar unde rSIngle and Combined Loadings, Meccanica, 47, 1141-1156, 2012.

Ismail, A.E., Ariffin, A.K., Abdullah, S., Ghazali, M.J., Stress intensity factors under mode III loadings, (2013) International Review of Mechanical Engineering (IREME), 7 (3), pp. 578-582.

Ismail, A.E., Ariffin, A.K., Abdullah, S., Ghazali, M.J., Effect of crack faces opening mechanisms on the combined stress intensity factors under bending and torsion moments, (2011) International Review on Modelling and Simulations (IREMOS), 4 (6), pp. 3232-3238.

C. F. Shih, B. Moran and T. Nakamura, Energy Release Rate along a Three-Dimensional Crack Front in a Thermally Stressed Body, Journal of Fracture, 30 (2), 79-102, 1986.

S. Courtin, C. Gardin, G. Be´zine and H. Ben Hadj Hamouda, Advantages of the J-integral Approach for Calculating Stress Intensity Factors when Using the Commercial Finite Element Software ABAQUS, Engineering Fracture Mechanics, 72, 2174–2185, 2005.

M.C Walters, G.H Pauline and R.H Dodds Jr, Interaction Integral Procedures for 3D Curved Cracks Including Surface Tractions, Engineering Fracture Mechanics, Vol. 72, pp. 1635-1663, 2005.

ANSYS Manual User Guide, 2013.