Numerical analysis of the welding process of steel-aluminum welding connector
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Abstract
The paper presents the results of the numeric welding simulation performed for S235JR-aluminum A5083 transition joint. The paper presents material parameters used in the model calculations. Results of the first calculations were presented in the form of the residual stresses distributions induced by the process of joining materials.
in polish
Analiza numeryczna procesu spawania łącznika spawalniczego stal-aluminium
W pracy zaprezentowano wyniki symulacji procesu spawania łącznika spawalniczego o konfiguracji stal S235JR- aluminium A5083 z międzywarstwą tytanu Grade 1 oraz aluminium A1050. W publikacji zaprezentowano parametry materiałowe modelu, a także wyniki pierwszych obliczeń w postaci rozkładów temperatury oraz naprężeń własnych wywołanych przez proces łączenia materiałów.
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References
Altenpohl D.: Aluminium und Aluminiumlegierungen, Springer-Verlag, Berlin Heidelberg, 1965.
Goldak J., Chakravarti A., Bibby M.: A new finite element model for welding heat sources, MTB. 15, 1984, pp. 299-305.
Knoedel P., Gkatzogiannis S., Ummenhofer T.: Practical aspects of welding residual stress simulation, Journal of Constructional Steel Research. 132, 2017, pp. 83-96.
Kumar Singh S., Mohan Tiwari R., Kumar A., Kumar S., Qasim Murtaza, S. Kumar: Mechanical Properties and Microstructure of Al-5083 by TIG, Materials Today: Proceedings. 5, 2018, pp. 819-822.
Liu W., Ma J., Mazar Atabaki M., Kovacevic R.: Joining of advanced high-strength steel to AA 6061 alloy by using Fe/Al structural transition joint, Materials & Design. 68, 2015, pp. 146-157.
Purdue University, Thermophysical Properties Research Center, Y.S. Touloukian, C.Y. Ho: Properties of aluminum and aluminum alloys, Thermo-physical Properties Research Center, Purdue University, West Lafayette, Ind., 1973.
Rathod M., Kutsuna M.: Joining of Aluminum Alloy 5052 and Low-Carbon Steel by Laser Roll Welding, Welding Journal., 2004, pp. 16-26.
Schoer H.: Schweißen und Hartlöten von Aluminiumwerkstoffen, 2nd ed., DVS Media GmbH, Düsseldorf, 2003.
Seyffarth P., Scharff A., Meyer B.: Grosser Atlas Schweiss-ZTU- Schaubilder, DVS Me-dia GmbH, Düsseldorf, 1992.
Yogo Y., Sawamura M., Harada R., Miyata K., Iwata N., Ishikawa T.: Stress-strain curve of pure aluminum in a super large strain range with strain rate and temperature dependency, Procedia Engineering. 207, 2017, pp. 161-166.