PSI - Issue 26

Sabrina Vantadori et al. / Procedia Structural Integrity 26 (2020) 106–112 Vantadori et al. / Structural Integrity Procedia 00 (2019) 000 – 000

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Acknowledgements

The authors gratefully acknowledge the financial support of the Italian Ministry of Education, University and Research (MIUR), Research Grant PRIN 2017 No. 2017HFPKZY on “Modelling of constitutive laws for traditional and innovative buildi ng materials”. References Araújo J.A. , Dantas A.P., Castro F.C., Mamiya, E.N., Ferreira J.L.A., 2011. On the characterization of the critical plane with a simple and fast alternative measure of the shear stress amplitude in multiaxial fatigue. International Journal of Fatigue 33, 1092 1100. Araújo J.A., Carpinteri A., Ronchei C., Spagnoli A., Vantadori S., 2014. An alternative definition of the shear stress amplitude based on the Maximum Rectangular Hull method and application to the C-S (Carpinteri-Spagnoli) criterion. Fatigue and Fracture of Engineering Materials and Structures 37, 764-771. Carpinteri A., Spagnoli A., Vantadori S., 2011. Multiaxial fatigue assessment using a simplified critical plane-based criterion. International Journal of Fatigue 33, 969-76. Carpinteri A., Ronchei C., Spagnoli A., Vantadori S., 2014. On the use of the Prismatic Hull method in a critical plane-based multiaxial fatigue criterion . International Journal of Fatigue 68, 159-167. Carpinteri A., Ronchei C., Scorza D., Vantadori S., 2015. Critical plane orientation influence on multiaxial high-cycle fatigue assessment. Physical Mesomechaics 18, 348-354. Carpinteri A., Boaretto J., Fortese G., Giordani F., Iturrioz I., Ronchei C., Scorza D., Vantadori S., 2017. Fatigue life estimation of fillet-welded tubular T-joints subjected to multiaxial loading. International Journal of Fatigue 101, 263-270. Carpinteri A., Vantadori S., Zanichelli A., 2019. Lifetime estimation of mechanical assemblies under constant amplitude fretting fatigue loading. Fatigue and Fracture of Engineering Materials and Structures 42, 1927-1936. Chmelko V., Margetin M., 2020. The performance of selected multiaxial criteria under tension/torsion loading conditions. International Journal of Fatigue 135, 105532. Cruces A.S., Lopez ‐ Crespo P., Bressan S., Itoh T., 2019. Investigation of the multiaxial fatigue behaviour of 316 stainless steel based on critical plane method. Fatigue and Fracture of Engineering Materials and Structures 42, 1633 – 1645. de Freitas M., 2017. Multiaxial fatigue: From materials testing to life prediction. Theoretical and Applied Fracture Mechanics 92, 360-372. Fatemi A., Shamsaei N., 2011. Multiaxial fatigue: An overview and some approximation models for life estimation. International Journal of Fatigue 33, 948-958. Hu Z., Berto F., Hong Y., Susmel L., 2019. Comparison of TCD and SED methods in fatigue lifetime assessment. International Journal of Fatigue 123, 105-134. Itoh T., Yang T., 2011. Material dependence of multiaxial low cycle fatigue lives under non-proportional loading. International Journal of Fatigue 33, 1025 – 1031. Morishita T., Itoh T., Bao Z., 2016. Multiaxial fatigue strength of type 316 stainless steel under push-pull, reversed torsion, cyclic inner and outer pressure loading. International Journal of Pressure Vessels and Piping 140, 228 – 236. Morishita T., Takada Y., Ogawa F., Hiyoshi N., Itoh T., 2018. Multiaxial fatigue properties of stainless steel under seven loading paths consisting of cyclic inner pressure and push-pull loading. Theoretical and Applied Fracture Mechanics 96, 387 – 397. Socie D.F., Marquis G.B., 2000. Multiaxial Fatigue. Warrendale, PA (USA): Society of Automotive Engineers, Inc. Xue L., Shang D.-G., Li D.-H., Li L.-J., Xia Y., Hui J., 2020. Online multiaxial fatigue damage evaluation method byreal-time cycle counting and energy-based critical plane criterion. Fatigue and Fracture of Engineering Materials and Structures, doi: 10.1111/ffe.12991.