PSI - Issue 42

Jan Klusák et al. / Procedia Structural Integrity 42 (2022) 1369–1375 Author name / Structural Integrity Procedia 00 (2019) 000 – 000

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Failure of the specimens had developed from extrusions and intrusions on the surface of specimens. No internal crack initiation was observed. Knowledge of the fatigue behavior of the studied stainless steels can contribute to more reliable design of steel structures. Acknowledgements Authors are grateful for the support of the research through the project No. 20-00761S (Influence of material properties of stainless steels on reliability of bridge structures) of the Czech Science Foundation. References Basquin, O.H. (1910). The exponential law of endurance tests. Proceedings of ASTM. Vol. 10(II). pp. 625-630. Gardner, L. (2005). The use of stainless steel in structures, Progress in Structural Engineering and Materials 7(2): 45 – 55 Jambor M., Vojtek T., Pokorný P., Šmíd M. (2021) Effect of Solution Annealing on Fatigue Crack Propagation in the AISI 304L TRIP Steel. Materials 14, 1331 Klesnil, M., Lukáš, P. (1992) Fatigue of Metallic Materials, Elsevier Lo, K.H., Shek, C.H. and Lai, J.K.L. (2009), Recent developments in stainless steels, Mater. Sci. Eng. R Rep., 65, pp. 39-104. Michler, T., Naumann, J., Balogh, M. (2014), Hydrogen environment embrittlement of solution treated Fe – Cr – Ni super alloys, Mater Sci Eng A, 607, 71-80. Michler, T., Naumann, J., Wiebesiek, J., Sattler, E. (2017), Influence of frequency and wave form on S-N fatigue of commercial austenitic stainless steels with different nickel contents in inert gas and in high pressure gaseous hydrogen, International Journal of Fatigue 96, 67-77. Polák, J. (1991). Cyclic plasticity and low cycle fatigue life of metals. Amsterdam: Elsevier. Polák, J. , Mazánová, V., Heczko, M., Petráš, R., Kuběna, I., Casalena, L., Man, J., (2017), The role of extrusions and intrusions in fatigue crack initiation, Engineering Fracture Mechanics, 185, 46-60. Seitl, S., Pokorný, P., Klusák, J., Duda, S., Lesiuk, G. (2022). Effect of Specimen Thickness on Fatigue Crack Growth Resistance in Paris Region in AISI 304 Steel, Fatigue and Fracture of Materials and Structures. Structural Integrity, Vol. 24. Springer Seitl S., Miarka P., Klusák J., Fintová S., Kunz L. (2018), Comparison of the fatigue crack propagation rates in S355 J0 and S355 J2 steel grades, Key Engineering Materials, 784, 91 – 96 Seitl S., Miarka P., Klusák J., Kala Z., Krejsa M., Blasón S., Canteli A.F. (2018a) Evaluation of fatigue properties of S355 J0 steel using ProFatigue and ProPagation software, Procedia Structural Integrity, 13, 1494 – 1501 Suresh, S. (1998) Fatigue of Materials, 2nd ed.; Cambridge University Press: Cambridge, UK, 541 – 544. Šmíd, M., Kuběna, I., Jambor, M., Fintová, S., 2021, Effect of solution annealing on low cycle fatigue of 304L stainless stee l, Materials Science and Engineering: A, Volume 824, 141807. Trávníček L., Kuběna I., Mazánová V., Vojtek T ., Polák J., Hutař P., Šmíd M. (2021) Advantageous Description of Short Fatigue Crack Growth Rates in Austenitic Stainless Steels with Distinct Properties. Metals 11, 475. Baddoo, N.R. (2008). Stainless steel in construction: A review of research, applications, challenges and opportunities, Journal of Constructional Steel Research 64(11): 1199 – 1206