PSI - Issue 51

Milan Uhríčik et al. / Procedia Structural Integrity 51 (2023) 166 – 172 M. Uhrí č ik et al. / Structural Integrity Procedia 00 (2022) 000–000

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Acknowledgements The research was supported by the Scientific Grant Agency of the Ministry of Education of Slovak Republic and Slovak Academy of Sciences, VEGA 01/0134/20 and KEGA 004ŽU-4/2023, project APVV-20-0427 and projects to support young researchers at UNIZA, the ID of projects 14877 and 12715. References Belan, J., Kuchariková, L., Vaško, A., Tillová, E., Chalupová, M., Matvija, M. ,2020. The SEM and TEM analysis of IN718 alloy after fatigue push-pull loading at 700 °C. Trans Tech Publications 405, 288-293. Borgioli, F., Fossati, A., Galvanetto, E., Bacci, T., 2005. Glow-discharge nitriding of AISI 316L austenitic stainless steel: influence of treatment temperature. Surface and Coatings Technology 200, 2474-2480. Ç etinarslan, C. S., sahin, M., Karaman Gen ç , S., Sevil, C., 2012. Mechanical and metallurgical properties of ion-nitrided austenitic-stainless steel welds. Materials Science-Poland 30, 303-312. Collins, G. A., Hutchings, R., Short, K. T., Tendys, J., Van Der Valk, C. H., 1996. Development of a plasma immersion ion implanter for the surface treatment of metal components. Surface and Coatings Technology 84, 537-543. Dearnley, P. A., Namvar, A., Hibberd, G. G. A., Bell, T., 1989. Some observations on plasma nitriding austenitic stainless steel. In: Proceedings of the 1 st International Conference on Plasma Surface Engineering, Garmisch-Partenkirchen, 1988, DGM Informtionsgesellschaft, Oberursel, pp. 219. Fernandes, F. A, P., Lombardi Neto, A., Casteletti, L. C., Oliveira, A. M., Totten, G. E., 2008. Stainless steel property improvement by ion nitriding and nitrocarburizing. Heat Treating Progress 8, 41-43. Fontes, M. A., Pereire, R. G., Fernandes, F. A, P., Casteletti, L. C., Nascente, P. A. de P., 2014. Characterization of plasma nitride layers produced on sintered iron. Journal of Materials Research and Technology 3, 210-216. Ichii, K., Fujimura, K., Takase, T., 1986. Structure of the ion-nitrided layer of 18-8 stainless steel. In: Technology Reports of Kansai University no. 27. Konečná, R., Nicoletto, G., 2020. Near-surface structure and fatigue crack initiation mechanisms of as-built SLM Inconel 718. Trans Tech Publications 405, 306-311. Kuchariková, L., Tillová, E., Chalupová, M., Belan, J., Švecová, I., Vaško, A., 2017. Study of artificial aging temperature effect on morphology of structural parameters in aluminium cast alloy. Trans Tech Publications 891, 354-359. Larisch, B., Brusky, U., Spies, H.-J., 1999.Plasma nitriding of stainless steels at low temperatures. Surface and Coatings Technology 116-119, 205 211. Major S., 2020. Utilization normal vectors for description of fracture surfaces. Procedia Structural Integrity 28, 561-576. Menthe, E., Rie, K.-T., Schultze, J. W., Simson, S., 1995. Structure and properties of plasma-nitrided stainless steel. Surface and Coatings Technology 74-75, 412-416. Menthe, E., Rie, K.-T., 1999. Further investigation of the structure and properties of austenitic stainless steel after plasma nitriding. Surface and Coatings Technology 116-119, 119-204. Muñoz Riofano, R. M., Casteletti, L. C., Nascente, P. A. P., 2006. Study of the wear behavior of ion nitride steels with different vanadium contents. Surface and Coatings Technology 200, 6101-6110. Saker, A., Leroy, C., Michel, H., Frantz, C., 1991. Properties of sputtered stainless steel-nitrogen coatings and structural analogy with low temperature plasma nitride layers of austenitic steels. Materials Science and Engineering:A 140, 702-708.