PSI - Issue 72

Levente Tatár et al. / Procedia Structural Integrity 72 (2025) 345–353

353

References Bridgman, P. W. 1952. Studies in Large Plastic Flow and Fracture with Special Emphasis on the Effects of Hydrostatic Pressure. McGraw ‐ Hill, New York Choung, J., Cho, S-R. 2008. Study on true stress correction from tensile tests. Journal of Mechanical Science and Technology 22, 1039 – 1051 Considère, A. 1885. Mémoire sur l’emploi du fer et de l’acier dans les constructions. Annales des Ponts et Chaussées 9. Paris, Ch. Dunod, 574 – 605 Fekete, T.; Antók, D.; Tatár, L.; Bereczki, P. 2024. Investigation on geometric imperfections of tensile test specimens using optical full-field measurements and digital twin-based simulations. Procedia Structural Integrity 54, 314 – 321 Grossbeck, M.L., Maziasz P.J. 1979. Tensile properties of type 316 stainless steel irradiated in a simulated fusion reactor environment, Journal of Nuclear Materials 85 – 86, Part 2, 883 – 887 Hexagon MARC/Mentat. 2025. https://hexagon.com/products/marc ImageMagick. 2025. https://imagemagick.org/index.php Sharma, A., Kosasih, A., Zhang, J., Brintrup, A., Calinescu A. 2022. Digital Twins: State of the art theory and practice, challenges, and open research questions, Journal of Industrial Information Integration 30 Tsukahara, H., Iung, T., 1998. Finite element simulation of the Piobert – Lüders behavior in a uniaxial tensile test. Materials Science and Engineering A. Structural Material Properties 248, 304 – 308 Tvergaard, V., Needleman, A. 1984. Analysis of the cup-cone fracture in a round tensile bar. Acta Metallurgica 32(1), 157-169 Wilkins, M L, Streit, R D, Reaugh, J E. 1980. Cumulative-strain-damage model of ductile fracture: simulation and prediction of engineering fracture tests. Lawrence Livermore National Laboratory. University of California. Livermore, California