Author:
Weidner Anja,Wagner Ruben,Seleznev Mikhail,Biermann Horst
Abstract
AbstractThis chapter presents results on the analysis of nonmetallic as well as intermetallic inclusions within a metal matrix. In both, steel and aluminum matrix these impurities cause detrimental effects during production as well as in service, e.g. under mechanical load. In steel, nonmetallic inclusions originate from the steelmaking process and range in the magnitude of ppm. In recycled aluminum alloys, iron-rich intermetallic phases exhibit a volume fraction in the range of percent caused by insufficient scrap separation. Both types of detrimental inclusions/precipitates were investigated within different materials such as case hardening steel, quenched and tempered steel as well as Al-Si cast alloy. In order to reduce the amount of impurities, the effects of appropriate crucible materials, reactive and active melt filtration and chemical composition of the used materials were studied. Therefore, extensive metallographic investigations on sections were conducted with optical microscopy, manual and automated scanning electron microscopy, focused ion beam preparation and transmission electron microscopy aiming to determine the compositions of inclusions and intermetallic phases. Focusing on the morphology of inclusions and intermetallic phases, experiments with electrolytic and chemical extraction as well as X-ray micro tomography were performed. The gained knowledge can be utilized to improve filtration and reduce volume fraction and size of nonmetallic inclusions and intermetallic phases. This enables the design of long-lasting and safe materials.
Publisher
Springer International Publishing
Reference57 articles.
1. A.L.V. Da Costa e Silva, J. Mater. Res. Technol. 7(3), 283 (2018). https://doi.org/10.1016/j.jmrt.2018.04.003
2. L. Zhang, B.G. Thomas (eds.), Inclusions in Continuous Casting of Steel. XXIV National Steelmaking Symposium, Morelia, Mich, Mexico, 2003
3. R.P. Batista, A.A. Martins, A.L.V.d. Costa e Silva, J. Min. Metall. B Metall. 53(3), 357 (2017). https://doi.org/10.2298/JMMB170730047P
4. L.D. Way, Mater. Sci. Technol. 17(10), 1175 (2001). https://doi.org/10.1179/026708301101509142
5. M. Seleznev, S. Henschel, E. Storti, C.G. Aneziris, L. Krüger, A. Weidner, H. Biermann, Adv. Eng. Mater. 50(22), 1900540 (2020). https://doi.org/10.1002/adem.201900540