PSI - Issue 39

A.L. Pinto et al. / Procedia Structural Integrity 39 (2022) 409–418 Author name / Structural Integrity Procedia 00 (2019) 000–000

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iii. Furthermore, it is worth mentioning that besides providing better crack initiation direction estimates, Method 1 is considerably easier to implement and presents a very small computational cost compared to Method 2, which involves crack propagation simulation. Acknowledgements The authors would like to acknowledge the financial support of TBE (Transmissoras Brasileira de Energia) in the context of the project entitled “Fadiga de Cabos de Alumínio Liga (CAL) 1120 e 6201: estudo comparativo, efeito de grampos AGS e de emendas pré-formadas”. This project has been developed within the Program of Research and Technological Development from the Electricity Energy Sector regulated by ANEEL. References Almeida, G. M. J., Pessoa, G. C. V., Cardoso, R. A., Castro, F. C., & Araújo, J. A. (2020). Investigation of crack initiation path in AA7050-T7451 under fretting conditions. Tribology International, 144, 106103. Araújo, J. A., Susmel, L., Taylor, D., Ferro, J. C. T., & Ferreira, J. L. A. (2008). On the prediction of high-cycle fretting fatigue strength: Theory of critical distances vs. hot-spot approach. Engineering Fracture Mechanics, 75(7), 1763-1778. Araújo, J. A., Susmel, L., Taylor, D., Ferro, J. C. T., & Mamiya, E. N. (2007). On the use of the Theory of Critical Distances and the Modified Wöhler Curve Method to estimate fretting fatigue strength of cylindrical contacts. International journal of fatigue, 29(1), 95-107. Araújo, J. A., Almeida, G. M. J., Ferreira, J. L. A., da Silva, C. R. M., & Castro, F. C. (2017). Early cracking orientation under high stress gradients: The fretting case. International Journal of Fatigue, 100, 611-618. Bhatti, N. A., & Wahab, M. A. (2018). Fretting fatigue crack nucleation: a review. Tribology International, 121, 121-138. Baietto, M. C., Pierres, E., Gravouil, A., Berthel, B., Fouvry, S., & Trolle, B. (2013). Fretting fatigue crack growth simulation based on a combined experimental and XFEM strategy. International Journal of Fatigue, 47, 31-43. Cardoso, R. A., Araújo, J. A., Ferreira, J. L. A., & Castro, F. C. (2016). Crack path simulation for cylindrical contact under fretting conditions. Frattura ed Integrità Strutturale, 10(35), 405-413. Carpinteri, A., Spagnoli, A., & Vantadori, S. (2011). Multiaxial fatigue assessment using a simplified critical plane-based criterion. International Journal of Fatigue, 33(8), 969-976. Cheng, W. H. S. T., Cheng, H. S., Mura, T., & Keer, L. M. (1994). Micromechanics modeling of crack initiation under contact fatigue. Fouvry, S., Nowell, D., Kubiak, K., &Hills, D. A. (2008). Prediction of fretting crack propagation based on a short crack methodology. Engineering Fracture Mechanics, 75(6), 1605-1622. Fouvry, S., Gallien, H., & Berthel, B. (2014). From uni-to multi-axial fretting-fatigue crack nucleation: Development of a stress-gradient-dependent critical distance approach. International Journal of Fatigue, 62, 194-209. Lamacq, V., Dubourg, M. C., & Vincent, L. (1997). A theoretical model for the prediction of fretting fatigue crack initial growth angles and sites. Tribology Int, 30(6), 391-400. Neu, R. W., Pape, J. A., & Swalla, D. R. (2000). Methodologies for linking nucleation and propagation approaches for predicting life under fretting fatigue. In Fretting fatigue: current technology and practices. ASTM International. Ruiz, C., & Chen, K. C. (1986). Life assessment of dovetail joints between blades and discs in aero-engines. Mechanical Engineering Publications,, 187-194. Szolwinski, M. P., & Farris, T. N. (1996). Mechanics of fretting fatigue crack formation. Wear, 198(1-2), 93-107. Smith, R. N., Watson, P., & Topper, T. H. (1970). A stress-strain parameter for the fatigue of metals. Journal of Materials, 5(4), 767-778. Taylor, D., & Wang, G. (2000). The validation of some methods of notch fatigue analysis. Fatigue & fracture of engineering materials & structures (Print), 23(5), 387-394. Vantadori, S., Almeida, G. M. J., Fortese, G., Pessoa, G. C. V., & Araujo, J. A. (2018). Early fretting crack orientation by using the critical plane approach. International Journal of Fatigue, 114, 282-288. Vingsbo, O., & Söderberg, S. (1988). On fretting maps. Wear, 126(2), 131-147.