Microstructural Characterization of Antimony Modified Carbidic Austempered Ductile Iron

A. Barnabas, A. Oyetunji, S. Seidu
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引用次数: 2

Abstract

In this research, Scanning Electron Microscope (SEM) analysis was conducted on the produced antimony modified carbidic austempered ductile iron for agricultural implement production. Six different alloys of carbidic austempered ductile iron with varying micro quantities of antimony elements were produced. The produced alloys were heated to austenitic temperature of 910oC, held at this temperature for 1 hour, finally subjected to austempering temperatures of 300°C and 325°C for periods of 1-3 hours. The SEM in conjunction with XRD and EDS was used for the analysis. Microstructural phase morphology, phase constituents and phase compositions were viewed with SEM, XRD and EDS respectively. The results show that various phases such as spiky graphite, blocky carbides, granular carbide, pearlite and ausferrite matrix. The XRD pattern revealed some compounds such as (Fe, Cr)3C, (primary carbide), Cr6C23 (few secondary carbide), (NiFe2O4), chromite (FeCr2O4), Cr7C3 (few eutectic carbide) and Cr3Ni2. In conclusion, it was observed in terms of morphology that chunky graphite, blocky carbide and pearlite phases were present in the cast carbidic ductile iron (CDI) without antimony addition. The CDI with varying quantities of antimony additions shows spiky graphite, granular carbides and pearlite matrix. After the samples were subjected to austempering processes, all the phases were found to be intact except the pearlite phase that transformed to ausferrite phase. The antimony element in the alloys was seen to promote the formation of pearlite phase intensively. The hardness of the samples increases as the antimony addition increases from 0.096wt.% to 0.288wt.% owing to the increase in pearlite phase, while the impact toughness reaches relatively high level, when 0.288wt.% antimony was added, probably due to the refinement of graphite nodules. All the results obtained showed that appropriate content of antimony addition plays an important role in increasing the nucleation rate of graphite nodules, and also lead to improvement in carbide formation thereby providing good balance between wear and impact properties.
锑改性碳化物奥贝球铁的显微组织表征
对生产的农具用锑改性碳化物等温球墨铸铁进行了扫描电镜(SEM)分析。采用不同微量的锑元素制备了6种不同的碳化物等温球铁合金。将生产的合金加热到910℃的奥氏体温度,在此温度下保持1小时,最后进行300℃和325℃的等温回火1-3小时。采用SEM、XRD、EDS分析。分别用SEM、XRD和EDS观察了显微组织相形貌、相组成和相组成。结果表明:合金中存在尖状石墨、块状碳化物、粒状碳化物、珠光体和奥氏体基体等多种相;XRD谱图显示出(Fe, Cr)3C、(原生碳化物)、Cr6C23(少量次生碳化物)、(NiFe2O4)、铬铁矿(FeCr2O4)、Cr7C3(少量共晶碳化物)和Cr3Ni2等化合物。综上所述,在未添加锑的铸态碳化物球墨铸铁(CDI)中存在块状石墨相、块状碳化物相和珠光体相。不同锑添加量的CDI显示出尖刺状石墨、粒状碳化物和珠光体基体。样品经等温回火处理后,除珠光体相转变为奥铁素体相外,其余相均完好无损。合金中的锑元素强烈地促进珠光体相的形成。样品硬度从0.096wt开始随锑添加量的增加而增加。%至0.288磅。%由于珠光体相的增加,而冲击韧性达到了较高的水平,达到0.288wt。添加了锑,可能是由于石墨结核的细化。结果表明,适当的锑添加量对提高石墨结核的成核速率有重要作用,并能改善碳化物的形成,从而在磨损和冲击性能之间取得良好的平衡。
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