A Novel Processing Route in the Mechano-Synthesis of Austenitic 58Fe25Ni17Cr Oxide Dispersion Strengthened Cast Alloy through Y2O3 Pre-Linking

Parikin Farihin, Bambang Suharno, Mohammad Dani, Andryansyah Andryansyah, Dian Adi Prastowo, Andon Insani, Djoko Hadi Prayitno
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Abstract

A powder metallurgical process has been applied to synthesize the FeNiCr+Y2O3 oxide dispersion strengthened (ODS) alloys. The composition of the reinforcing Y2O3 added into matrix was varied from zero to 2.0 percent weight. Raw powders were carefully weighed with a four-digit balance. Y2O3 powder was pre-linked into Fe powder as the dominant element in the matrix by manually ground for half an hour. Ni and Cr powders were then mixed evenly for the next a half hour to obtain FeNiCr+Y2O3 precursor. Avoiding agglomeration and grain coarsening, the precursor was uniformly homogenized by milling for 20 hours. The precursors were then compressed at an isostatic pressure of 100 kN to 12 grams of pellets each. To prevent sample erosion during smelting with an electric arc furnace (EAF), crystal growing mechanism by conventional sintering was performed at 900 °C for 2 hours. This strengthens the bonds between precursors in forming ODS alloys. The samples were then melt-casted in the arc by 4 times flips. As a result, the neutron diffraction analysis and SEM-EDS strongly reveal the austenitic crystal structure and Y2O3 oxide successfully dispersed in the cast-alloy respectively. The microstructures with Y2O3 oxide spread uniformly overall the cast-alloy surfaces.
通过 Y2O3 预连接奥氏体 58Fe25Ni17Cr 氧化物弥散强化铸造合金的机械合成新工艺路线
采用粉末冶金工艺合成了铁镍铬+Y2O3 氧化物分散强化(ODS)合金。添加到基体中的强化 Y2O3 的重量百分比从 0% 到 2.0% 不等。原料粉末用四位天平仔细称量。通过人工研磨半小时,将 Y2O3 粉末预先连接到基体中的主要元素铁粉中。然后将镍粉和铬粉均匀混合半小时,得到 FeNiCr+Y2O3 前驱体。为了避免团聚和晶粒粗化,前驱体经过 20 小时的研磨均匀匀化。然后在 100 千牛的等静压下将前驱体压缩成 12 克的颗粒。为防止样品在电弧炉(EAF)熔炼过程中受到侵蚀,采用常规烧结法在 900 ℃ 下烧结 2 小时,以强化晶体生长机制。这加强了形成 ODS 合金的前驱体之间的结合。然后,样品在电弧中进行 4 次翻转熔铸。结果,中子衍射分析和 SEM-EDS 分别强烈显示出奥氏体晶体结构和 Y2O3 氧化物成功地分散在铸造合金中。带有 Y2O3 氧化物的微观结构均匀地分布在整个铸铝表面。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
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