PSI - Issue 66

Johannes L. Otto et al. / Procedia Structural Integrity 66 (2024) 256–264 Johannes L. Otto et al. / Structural Integrity Procedia 00 (2025) 000–000

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Acknowledgements The authors gratefully acknowledge the funding by the German Research Foundation (Deutsche Forschungsgemeinschaft, DFG) for the project “Alloying- and microstructure-based fatigue life characterisation and prediction of vacuum brazed AISI 304L/NiFeCrSiB joints in corrosive environments” (project no. 408904168). References Almubarak, A., Abuhaimed, W., Almazrouee, A., 2013. Corrosion behavior of the stressed sensitized austenitic stainless steels of high nitrogen content in Seawater. International Journal of Electrochemistry 2013 (1), 970835. Binesh, B., 2020. Diffusion brazing of IN718/AISI 316L dissimilar joint: Microstructure evolution and mechanical properties. Journal of Manufacturing Processes 57, 196-208. Bland, L. G., Locke, J. S., 2017. Chemical and electrochemical conditions within stress corrosion and corrosion fatigue cracks. npj Materials Degradation 12 (1), 1-8. Bobzin, K., Heinemann, H., Erck, M., Stryzhyboroda, O., Vinke, S., 2024. Novel Fe-based amorphous brazing foils in the quinary system Fe-Ni-Cr-Si-B. Advanced Engineering Materials 26, 2300403. Boretius, M., 2006. The potential of vacuum brazing – State of the art and developments from the perspective of a service contractor. Advanced Engineering Materials 8, 158-161. Chen, X., Gussev, M., Balonis, M., Bauchy, M., Sant, G., 2021. Emergence of micro-galvanic corrosion in plastically deformed austenitic stainless steels. Materials & Design 203, 109614. Cook III, G. O., Sorensen, C. D., 2011. Overview of transient liquid phase and partial transient liquid phase bonding. Journal of Materials Science 46, 5305-5323. Fedotov, I., Ivannikov, A., Terekhova, S., Dzhumaev, P., Kozlov, I., Svetogorov, R., Klyushin, I., Sevryukov, O., 2024. Brazing of ZTA ceramic with titanium for biomedical application. The International Journal of Advanced Manufacturing Technology 134, 4477-4487. Fujii, T, Ogasawara, N., Tohgo, K., Shimamura, Y., 2024. Monte Carlo simulation of stress corrosion cracking in welded metal with surface defects and life estimation. International Journal of Mechanical Sciences 270, 109079. Ma, H., Duan, P., Liao, P., Zhou, G., Tu, S., 2022. Effect of temperature on metallurgical reactions and microstructure evolution of 316L/BNi-2 brazed joints. Journal of Materials Engineering Performance 31, 1631-1641. Nazarov, A., Vivier, V., Vucko, F., Thierry, D., 2019. Effect of tensile stress on the passivity breakdown and repassivation of AISI 304 stainless steel: A scanning kelvin probe and scanning electrochemical microscopy study. Journal of The Electrochemical Society, 166 (11) C3207-C3219. Otto, J. L., Penyaz, M., Schmiedt-Kalenborn, A., Knyazeva, M., Ivannikov, A., Kalin, B., Walther, F., 2020. Effect of phase formation due to holding time of vacuum brazed AISI 304L/NiCrSiB joints on corrosion fatigue properties. Journal of Materials Research and Technology 9 (5), 10550 10558. Otto, J. L, Penyaz, M., Möhring, K., Gerdes, L., Schaum, T., Ivannikov, A., Schmiedt-Kalenborn, A., Kalin, B., Walther, F., 2021. Microstructure, residual stresses, and strain-rate-dependent deformation and fracture behavior of AISI 304L joints brazed with NiCrSiB filler metals. Metals 11, 593. Otto, J. L., Sauer, L. M., Brink, M., Schaum, T., Lingnau, L. A., Macias Barrientos, M., Walther, F., 2023. A 2D and 3D segmentation-based microstructure study on the role of brittle phases in diffusion brazed AISI 304L/NiCrSiFeMoB joints. Materials & Design 235, 112401. Penyaz, M. A., Ivannikov, A. A., Sevryukov, O. N., Kalin, B. A., 2021. Overview of nickel-based filler metals for brazing of austenitic stainless steels. Non-Ferrous Metals 1, 41-56. Shin, J. H., 2023. Effect of thermo-mechanical processing on initiation and propagation of stress corrosion cracking in 304L austenitic stainless steel. Metals 13 (8), 1458. Truman, J. E., 1977. The influence of chloride content, pH and temperature of test solution on the occurrence of stress corrosion cracking with austenitic stainless steel. Corrosion Science 17, 737-746. VDA recommendation 230-214 (2018). Resistance of metallic materials to condensate corrosion in exhaust-gas-carrying components. Berlin, Germany. Way, M., Willingham, J., Goodall, R., 2020. Brazing filler metals. International Materials Review 65, 257-285. Wu, H., Meng, X., Han, Y., Zhang, Y., Peng, Q., 2022. Effect of surface machining on stress corrosion cracking sensitivity of 304L and 316L austenite stainless steel. Proceedings of the 29th International Conference on Nuclear Engineering 5, 90466.