Impact of Sintering Temperature of the Mechanical Properties of a Fe20Cr20Mn20Ni20Ti10Co5V5 Medium Entropy Alloy

African journal of inter-multidisciplinary studies Pub Date : 2023-01-01 DOI:10.51415/ajims.v5i1.1103

Steadyman Chikumba, Veeredhi Rao

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Abstract

Medium entropy alloys (MEAs) are new emerging engineering alloys comprising four principal elements characterised by a low enthalpy of mixing and entropies of formation between 1 and 1.5 molar gas constant. They have high strength, wear, and thermal properties. MEAs have generated interest as an alternative material in the last two decades in nuclear, aerospace, and high strength engineering applications. In this research a medium entropy alloy Fe20Cr20Mn20Ni20Ti10Co5V5 with principal elements Fe, Cr, Mn, and Ni was fabricated using spark plasma sintering. Elemental powder mixture was sintered at temperatures of 870oC, 900oC and 950oC under 35 bar pressure under an inert argon atmosphere for 45 minutes using an FCT Systeme GmbH spark plasma sintering machine. After sand blasting the densities of the samples were measured before grinding, polishing, and etching for characterisation. Microstructure analysis was carried using scanning electron and optical microscopy. Microhardness was measured using Falcon 507 hardness tester, modulus using by Anton-Paar Nanoindenter and wear using Anton-Paar TRB3 Tribometer. The elements form a solid solution with presence of a hard μ phase and soft γ-phase were observed. The hardness of the alloys sintered at 870oC and 900oC were 397 and 424 Vickers respectively. The alloy sintered at 950oC showed a hardness of 674 Vickers. After annealing the hardness increased to 736 Vickers. The modulus of elasticity and creep resistance increased after heat treatment at 700oC.The other alloys showed a decrease in hardness and other properties after annealing. Unlike in steels, where annealing reduces, in this alloy annealing increased hardness at an appropriate temperature. Fe20Cr20Mn20Ni20Ti10Co5V5 MEA exhibited good thermal stability. Further work on the alloy will involve its crystallography, and feasibility for use elevated temperature energy applications such as fuel cells, turbines and wear resistant machine components.

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烧结温度对Fe20Cr20Mn20Ni20Ti10Co5V5中熵合金力学性能的影响

中熵合金(MEAs)是一种新兴的工程合金，由四种主要元素组成，其特点是混合焓低，形成熵在1 ~ 1.5摩尔气体常数之间。它们具有高强度，耐磨和热性能。在过去的二十年中，mea作为一种替代材料在核、航空航天和高强度工程应用中引起了人们的兴趣。采用火花等离子烧结法制备了以Fe、Cr、Mn、Ni为主要元素的中熵合金Fe20Cr20Mn20Ni20Ti10Co5V5。采用FCT Systeme GmbH公司的火花等离子烧结机，在35 bar的惰性氩气气氛下，在870℃、900℃和950℃的温度下烧结元素粉末混合物，烧结时间为45分钟。喷砂后，在研磨、抛光和蚀刻表征之前测量样品的密度。采用扫描电子显微镜和光学显微镜对其进行微观结构分析。显微硬度采用Falcon 507硬度计，模量采用Anton-Paar纳米压头，磨损采用Anton-Paar TRB3摩擦计。观察到这些元素形成了硬μ相和软γ相的固溶体。在870oC和900oC下烧结的合金硬度分别为397和424维氏。在950℃下烧结的合金硬度为674维氏。退火后硬度提高到736维氏。在700℃热处理后，其弹性模量和抗蠕变性能均有所提高。其他合金退火后的硬度和其他性能均有所下降。不像在钢中，退火降低，在这种合金退火增加硬度在适当的温度。Fe20Cr20Mn20Ni20Ti10Co5V5 MEA具有良好的热稳定性。该合金的进一步研究将涉及其晶体学，以及在燃料电池、涡轮机和耐磨机器部件等高温能源应用中的可行性。

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African journal of inter-multidisciplinary studies

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