ArticleName |
Effect of laser welding on the structure and mechanical properties of hot-rolled Al – Zn – Mg – Ca alloy sheets |
ArticleAuthorData |
National University of Science and Technology MISiS, Moscow, Russia1 ; Moscow Polytechnic University, Moscow, Russia2:
N. V. Letyagin, Lead Research Project Engineer at the Department of Metal Forming1, Associate Professor of the Scientific Activity Sector2, e-mail: n.v.letyagin@gmail.com
National University of Science and Technology MISiS, Moscow, Russia1 ; Moscow Polytechnic University, Moscow, Russia2:
T. K. Akopyan, Senior Researcher at the Department of Metal Forming1, Lead Researcher at the Department of Materials Science2
National University of Science and Technology MISiS, Moscow, Russia: P. A. Palkin, Master’s Degree Student at the Department of Metal Forming
Moscow Polytechnic University, Moscow, Russia: V. V. Ovchinnikov, Principal Researcher at the Department of Materials Science |
Abstract |
Recent years have seen an ever growing interest in hybrid forming technology, with a special focus on aluminium alloys, which conform with the strategy of reduced weight of parts while maintaining high strength. The problem of combining parts made of such materials into a single assembly unit is of relevance today, alongside the development of new high-tech aluminium alloys. This paper examines the applicability of laser welding for butt joining thin hot-rolled sheets of aluminium alloy Al – 5 Zn – 1.3 Mg – 1 Ca (Fe, Mn, Cu, Si) (wt. %). An unhomogenized ingot of the experimental alloy was hot-rolled at the temperature of 450 oC down to the thickness of 2 mm (reduction degree of 90%). Two sheets were joined together on a robot laser welding machine in an optimum mode, which ensures a visual quality of the seam with minimum porosity of the weld. Laser power — 2,400 W, laser beam speed — 10 m/sec, focal distance — 217 mm, shielding gas consumption rate — 15 L/min. A study of microstructure and physical and mechanical properties helped evaluate the effect of the selected welding parameters on weld seam formation. It was found that the laser processing helps form a high-quality weld joint with no cracks and with low porosity. The strength of such weld is at the following level: σв = 240 MPa, σ0,2 = 170 MPa, with the elongation of δ = 3%. The ultimate strength of the weld joint is 83 % and the yield point is 92.5% of the strength of the base metal. The obtained results suggest that laser welding can potentially be applicable to joining sheets made of experimental Al – 5 Zn – 1.3 Mg – 1 Ca (Fe, Mn, Cu, Si) (wt. %) alloys, which differ from 7ххх series alloys due to the presence of calcium-containing eutectic that ensures high crack resistance and good casting and welding processability.
Support for this research was provided under Grant No. 22-19-00121 by the Russian Science Foundation, https://rscf.ru/project/22-19-00121/. |
References |
1. Dimatteo V., Liverani E., Ascari A., Fortunato A. Weldability and mechanical properties of dissimilar laser welded aluminum alloys thin sheets produced by conventional rolling and Additive Manufacturing. Journal of Materials Processing Technology. 2022. Vol. 302. 117512. 2. Akopyan T. K., Letyagin N. V., Avxentieva N. N. High-tech alloys based on Al – Ca – La(–Mn) eutectic system for casting, metal forming and selective laser melting. Non-ferrous Metals. 2020. Vol. 1. pp. 52–59. DOI: 10.17580/nfm.2020.01.09 3. Cui L., Peng Z., Chang Y., He D. et al. Porosity, microstructure and mechanical property of welded joints produced by different laser welding processes in selective laser melting AlSi10Mg alloys. Optics and Laser Technology. 2022. Vol. 150. 107952. 4. Ascari A., Fortunato A., Liverani E., Gamberoni A., Tomesani L. New possibilities in the fabrication of hybrid components with big dimensions by means of selective laser melting (SLM). Physics Procedia. 2016. Vol. 83. pp. 839–846. 5. Altparmak S. C., Yardley V. A., Shi Z., Lin J. Challenges in additive manufacturing of high-strength aluminium alloys and current developments in hybrid additive manufacturing. International Journal of Lightweight Materials and Manufacture. 2021. Vol. 4. pp. 246–261. 6. Kashaev N., Ventzke V., Çam G. Prospects of laser beam welding and friction stir welding processes for aluminum airframe structural applications. Journal of Manufacturing Processes. 2018. Vol. 36. pp. 571–600. 7. Sadeghian A., Iqbal N. A review on dissimilar laser welding of steel-copper, steel-aluminum, aluminum-copper, and steel-nickel for electric vehicle battery manufacturing. Optics and Laser Technology. 2022. Vol. 146. 107595. 8. Yang J., Oliveira J. P., Li Y., Tan C. et al Laser techniques for dissimilar joining of aluminum alloys to steels: A critical review. Journal of Materials Processing Technology. 2022. Vol. 301. 117443. 9. Jiang J., Atkinson H. V., Wang Y. Microstructure and mechanical properties of 7005 aluminum alloy components formed by thixoforming. Journal of Materials Science & Technology. 2017. Vol. 33. pp. 379–388. 10. Shin J., Kim T., Kim D., Kim D., Kim K. Castability and mechanical properties of new 7xxx aluminum alloys for automotive chassis/body applications. Journal of Alloys and Compounds. 2017. Vol. 698. pp. 577–590. 11. Akopyan T. K., Gamin Y. V., Galkin S. P., Prosviryakov A. S. et al. Radialshear rolling of high-strength aluminum alloys: Finite element simulation and analysis of microstructure and mechanical properties. Materials Science and Engineering A. 2020. Vol. 786. 139424. 12. Shurkin P., Akopyan T., Prosviryakov A., Komissarov A., Korotkova N. Single track scanning experiment on the hypereutectic aluminum alloy Al – 8 % Zn – 7 % Ni – 3 % Mg. MATEC Web of Conferences. 2020. Vol. 326. 07001. 13. Akopyan T. K., Belov N. A. Approaches to the design of the new highstrength casting aluminum alloys of 7xxx series with high iron content. Non-ferrous Metals. 2016. No. 1. pp. 20–27. DOI: 10.17580/nfm.2016.01.04 14. Shurkin P. K., Dolbachev A. P., Naumova E. A., Doroshenko V. V. Effect of iron on the structure, hardening and physical properties of the alloys of the Al – Zn – Mg – Ca system. Tsvetnye Metally. 2018. No. 5. pp. 69–77. DOI: 10.17580/tsm.2018.05.10 15. Shurkin P. K., Belov N. A., Musin A. F., Samoshina M. E. Effect of calcium and silicon on the character of solidification and strengthening of the Al – 8 % Zn – 3 % Mg alloy. Physics of Metals and Metallography. 2020. Vol. 121, Iss. 2. pp. 135–142. 16. Shurkin P. K., Belov N. A., Musin A. F., Aksenov A. A. Novel high-strength casting Al – Zn –Mg –Ca – Fe aluminum alloy without heat treatment. Russian Journal of Non-Ferrous Metals. 2020. Vol. 61. pp. 179–187. 17. Shurkin P. K., Karpova Zh. A., Latypov R. A., Musin A. F. Properties of welded joints of the Al – Zn – Mg – Ca alloy doped by microadditivies of zirconium and scandium. Tsvetnye Metally. 2021. No. 2. pp. 84–92. DOI: 10.17580/tsm.2021.02.10 18. GOST 1497–84. Metals. Methods of tension test. Introduced: 01.01.1986. 19. GOST 6996–66. Welded joints. Methods of mechanical properties determination. Introduced: 01.01.1967. 20. Xu J., Rong Y., Huang Y., Wang P., Wang C. Key-hole induced porosity formation during laser welding. Journal of Materials Processing Technology. 2018. Vol. 252. pp. 720–727. 21. Norris J. T., Robino C. V., Hirschfeld D. A., Perricone M. J. Effects of laser parameters on porosity formation: investigating millimeter scale continuous wave Nd:YAG laser welds. Welding Journal. 2011. Vol. 17, Iss. 6. pp. 431–437. 22. Li K., Lu F., Guo S., Cui H., Tang X. Porosity sensitivity of A356 Al alloy during fiber laser welding. Transactions of Nonferrous Metals Society of China. 2015. Vol. 25. pp. 2516–2523. 23. ISO 13919-2–2017. Electron and laser-beam welded joints. Guidance on quality levels for imperfections. Part 2. Aluminium and its weldable alloys. 24. Neikov O. D., Naboychenko S. S., Yefimov N. A. Handbook of nonferrous metal powders: technologies and applications. 2nd ed. London, UK : Elseiver, 2018. 995 p. 25. Bao S., Tang K., Kvithyld A., Engh T., Tangstad M. Wetting of pure aluminium on graphite, SiC and Al2O3 in aluminium filtration. Transactions of Nonferrous Metals Society of China. 2012. Vol. 22. pp. 1930–1938. |