The Correlation between Solidification Rates, Microstructure Integrity and Tensile Plastic Behaviour in 4.2 wt.% Silicon Strengthened Ductile Iron

G. Angella, Marcello Taloni, R. Donnini, F. Zanardi
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引用次数: 2

Abstract

High Silicon Strengthened Ductile Iron (HSiSDI) with 4.2 wt.% of silicon was produced in Y-blocks with different thicknesses to investigate the effects of the solidification rate on microstructure integrity and tensile mechanical properties. With decreasing solidification rates, the graphite degeneracy with the appearance of chunky graphite became more significant at the highest silicon contents, so chemical ordering and graphite degeneracy seemed to be qualitative explanations of tensile property degradation. However, a deeper analysis of the relationship between solidification rate, microstructure and tensile properties was realized through an innovative approach based on the Matrix Assessment Diagram (MAD), where the parameters of Voce equation resulting from best-fitting the experimental tensile flow curves of a significant number of HSiSDI samples, were plotted. For 3.5 wt.% silicon content, the MAD analysis indicated that the microstructure was sound for any solidification rate, while for 4.5 wt.% the microstructure was sound only for the fastest solidification rates. For 4.2 wt.% silicon content the MAD analysis pointed out that the tensile plastic behaviour and the microstructure integrity was in between the 3.5 and 4.5 wt.% silicon contents, representing a composition threshold where the reliable microstructures were only found with the fastest solidification rates, while considerable variability was found for the slowest ones. Support to the MAD analysis results was given from microstructure observations.
4.2% wt.%硅强化球墨铸铁凝固速率、显微组织完整性与拉伸塑性性能的关系
制备了硅含量为4.2 wt.%的高硅强化球墨铸铁(HSiSDI),研究了凝固速率对其显微组织完整性和拉伸力学性能的影响。随着凝固速率的降低,在硅含量最高时,以块状石墨形式出现的石墨退化更为明显,因此化学有序和石墨退化似乎是拉伸性能退化的定性解释。然而,通过一种基于矩阵评估图(MAD)的创新方法,对凝固速率、微观组织和拉伸性能之间的关系进行了更深入的分析,其中绘制了Voce方程的参数,该参数是由最适合大量HSiSDI样品的实验拉伸流动曲线得出的。当硅含量为3.5 wt.%时,MAD分析表明微观组织在任何凝固速率下都是良好的,而当硅含量为4.5 wt.%时,微观组织仅在最快的凝固速率下是良好的。对于硅含量为4.2 wt.%的材料,MAD分析指出,拉伸塑性行为和微观组织完整性介于硅含量为3.5和4.5 wt.%之间,这代表了一个成分阈值,在这个阈值中,只有在最快的凝固速率下才能找到可靠的微观组织,而在最慢的凝固速率下则发现了相当大的变化。微观结构观察结果支持了MAD分析结果。
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