Microstructure of gray cast iron FG 24 subjected to heat treatment
Keywords:
gray iron, microstructure, annealing, lamellar graphite, ferriteAbstract
The microstructural characterization of the transformations that occur in gray iron FG 24 subjected to thermal treatment was carried out. Six samples of the alloy were annealed at the same temperature (740 °C) but for different times (2 hours in one treatment and 3 hours in the other), with furnace cooling. Microstructures of lamellar graphite flakes were obtained in both treatments in a ferrite matrix, with size 4 of graphite for two hours treatment and size 3 for three hours treatment. It was evidenced that type A distribution of the graphite is maintained in both cases. This property varied in the hardness profiles from 230 HB for the standard sample, to 160 HB for the longest residence time in the furnace.Downloads
References
Aristizábal, R.; Silva, C.; Pérez, P.; Stanek, V. y Katz, S. 2009: Studies of a Quenched Cupola Part II: The Behavior of C, Si, Mn and S in the Metallic Charge. AFS Transactions, 117(09-104): 693-708.
Catalina, A.; Guo, X.; Stefanescu, D.; Chuzhoy, L. y Pershing, M. 2000: Prediction of room temperature microstructure and mechanical properties in gray iron casting. AFS Transactions, 108(72): 247-257.
Dardati, P.; Godoy, L.; Celentano, D. y Bertorello, H. 2004: Modelo para la simulación numérica de la solidificación de la fundición dúctil. Mecánica Computacional, XXIII: 2653-2677.
Dardati, P.; Celentano, D.; Godoy, L.; Chiarella, A. y Schulz, B. 2009: Analysis of ductile cast iron solidification: numerical simulation and experimental validation. International Journal of Cast Metals Research, 22(5): 390-400.
Fernández-Pariente, I. y Belzunce-Varela, F. 2006: Influencia de diversos tratamientos térmicos en la microestructura de una fundición blanca con alto contenido en cromo. Revista de Metalurgia, 42(4): 279–286.
Guo, X.; Stefanescu, D.; Chuzhoy, L.; Pershing, M. y Biltgen, G. 1997: A mechanical properties model for ductile iron. AFS Transactions, 105(47): 47-54.
Harvey, J. y Noble, G. 2007: Inoculation of Cast Irons: An Overview. In: 55th Indian Foundry Congress 2007, p. 343-360.
Luddey, J.; Marulanda, A. y Mesa, D. 2007: Recuperación y soldabilidad de fundición de hierro. Scientia Et Technica, XIII(37): 237-242.
Murakami, T.; Inoue, T.; Shimura, H.; Nakano, M. y Sasaki, S. 2006: Damping and Tribological Properties of Fe–Si–C Cast Iron Prepared Using Various Heat Treatments. Materials Science and Engineering A, 432(1-2): 113-119.
Tong, X.; Zhou, H.; Ren, L.; Zhang, W. y Cui, R. 2009: Effects of Graphite Shape on Thermal Fatigue Resistance of Cast Iron with Biomimetic Non-smooth Surface. International Journal of Fatigue, 31(4): 668-677.
Zhao, H. y Liu, B. 2001: Modelling of stable and metastable eutectic transformation of spheroidal graphite iron casting. ISI J. International, 41(9): 986-991.
Wang, J.; Li, C.; Liu, H.; Yang, H.; Shen, B.; Gao, S. y Huang, S. 2006: The precipitation and transformation of secondary carbides in a high chromium cast iron. Materials Characterization, 56(13): 73-78.
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