Issue 35

H. Dündar et alii, Frattura ed Integrità Strutturale, 35 (2016) 360-367; DOI: 10.3221/IGF-ESIS.35.41 367 A CKNOWLEDGEMENTS he financial support by The Scientific and Technological Research Council of Turkey (TÜBİTAK) for this study under project no 113M407 is gratefully acknowledged. R EFERENCES [1] Wessel, C., Cisilino, A., Santi, O., Otegui, J., Chapetti, M., Numerical and experimental determination of three- dimensional multiple crack growth in fatigue, Theoretical and Applied Fracture Mechanics, 35 (2001) 47-58. [2] Jonesa, R., Peng, D., Pitt, S., Assessment of multiple flat elliptical cracks with interactions, Theoretical and Applied Fracture Mechanics, 38 (2002) 281-291. [3] Yan, X., Stress intensity factors for interacting cracks and complex crack configurations in linear elastic media, Engineering Failure Leonel, E.D., Venturini, W.S., Multiple random crack propagation using a boundary element formulation, Engineering Fracture Mechanics, 78 (2011) 1077-1090. [4] Analysis, 14 (2007) 179-195. [5] Gravouil, A., Moës, N., Belytschko, T., Non-planar 3D crack growth by the extended finite element and level sets- Part II: Level set update. Int. J. Numer. Meth. Engng, 53 (2002) 2569-2586. [6] Hsieh, J.H., Denda, M., Redondo, J., Marante, M.E., Flórez-López, J,. Electronic handbook of fracture: A Java-based boundary element program for fracture analysis of multiple curvilinear cracks in the general anisotropic solids. Advances in Engineering Software, 39 (2008) 395-406. [7] Pierres, E., Baietto, M.C., Gravouil, A. Experimental and numerical analysis of fretting crack formation based on 3D X-FEM frictional contact fatigue crack model, Comptes Rendus Mécanique, 339 (2011) 532-551. [8] Citarella, R., Cricrì, R., Comparison of DBEM and FEM crack path predictions in a notched shaft under torsion, Engineering Fracture Mechanics, 77 (2010) 1730-1749. [9] Bouchard, P.O., Bay, F., Chastel, Y., Numerical modelling of crack propagation: automatic remeshing and comparison of different criteria, Comput. Methods Appl. Mech. Engrg., 192 (2003) 3887-3908. [10] Ayhan, A.O., Simulation of three-dimensional fatigue crack propagation using enriched finite elements, Computers and Structures, 89 (2011) 801-812. [11] ANSYS, Version 12.0, Ansys Inc., Canonsburg, PA, USA, 2009. [12] Ayhan, A.O., Nied H.F., Stress intensity factors for three-dimensional surface cracks using enriched elements, Int. J. Numer. Meth. Engng., 54 (2002) 899-921. [13] Dündar, H., Ayhan, A.O., Finite element modeling of growing multiple three-dimensional cracks under cyclic loads, 10th International Fracture Conference, Kayseri, Turkey, April 24-25, 2014, 28-36. [14] Derya, M., Ayhan, A.O., Numerical simulation of three-dimensional mode-I crack propagation using FCPAS: First set of practical case studies, 10th International Fracture Conference, Kayseri, Turkey, April 24-25, 2014, 28-36. [15] Yan, X., Automated simulation of fatigue crack propagation for two-dimensional linear elastic fracture mechanics problems by boundary element method, Engineering Fracture Mechanics, 74 (2007) 2225-2246. [16] Erdogan, F., Sih, G.C., On the Crack Extension in Plane Loading and Transverse Shear, J. Basic Eng., 85 (1963) 519- 527. [17] Judt, O.P., Ricoeur, A., Crack growth simulation of multiple cracks systems applying remote contour interaction integrals, Theoretical and Applied Fracture Mechanics, 75 (2015) 78-88. T