STUDY TO MICROSTRUCTURE AND MECHANICAL PROPERTIES OF Mg-Zn-Fe-Cu-Co AS HIGH ENTROPY ALLOYS FOR URETERAL IMPLANT APPLICATION

IF 0.6 Q4 METALLURGY & METALLURGICAL ENGINEERING

Metalurgija Pub Date : 2021-04-29 DOI:10.14203/METALURGI.V36I1.584

Andi Mulya Ashari

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Abstract

Magnesium and its alloys are promising candidates for degradable materials with good biocompatibility. Alloys based on Mg-Zn-Fe-Cu-Co compositions were designed using the equiatomic method of high entropy alloy. This paper discusses the microstructure and mechanical properties of these new high entropy alloys. Pure Magnesium (60 µm), Zinc (45 µm), Fe (10 µm), Cu (63 µm), and Co (1 µm) powder were mixed and milled using a shaker mill at 700 rpm for the 1800s. The resulting milled powders were compacted and sintered at 300 MPa for 180s and 600 MPa for 120s. Sintering was performed at 700 o C for 2 hours in a tube vacuum furnace at a 5 °C/min heating rate under a high purity argon atmosphere. Microstructural analyses and mechanical tests were performed based on the American standard of testing and measurement. The a lloys were basically multiphase and crystalline. The 20Mg-20Zn-20Fe-20Cu-20Co alloy consisted of the HCP phase and cubic phase. The physical and mechanical properties of Mg-Zn-Fe-Cu-Co were affected by the magnesium content in the matrix alloys. The presence of pores indicated uncomplete compaction and sintering process. The alloys have a medium hardness of between 286.06 HV - 80.98 HV, while the densities of the alloys were relatively moderate in the range of 3.057 g.cm -3 to 1.71 g.cm -3 . Solid solution and intermetallic precipitation strengthening were believed the primary strengthening mechanics of the alloys. It is concluded that high entropy is a promising method for the processing of Mg alloys. Alloy with a chemical composition of 20Mg-20Zn-20Fe-20Cu-20Co had optimal mechanical properties that meet the minimum requirements of high entropy alloys as candidates for ureteral implant applications.

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尿素离子注入用Mg-Zn-Fe-Cu-Co高熵合金的组织与力学性能研究

镁及其合金是一种具有良好生物相容性的可降解材料。采用高熵合金的等原子方法设计了基于Mg-Zn-Fe-Cu-Co成分的合金。本文讨论了这些新型高熵合金的微观结构和力学性能。将纯镁（60µm）、锌（45µm），Fe（10µm）和Cu（63µm）以及Co（1µm）粉末混合，并使用振动磨机在700 rpm下研磨19世纪。将得到的研磨粉末压实并在300MPa下烧结180s和600MPa下烧结120s。在高纯氩气气氛下，在管式真空炉中以5°C/min的加热速率在700℃下进行烧结2小时。微观结构分析和力学测试是根据美国测试和测量标准进行的。a合金基本上是多相的和结晶的。20Mg-20Zn-20Fe-20Cu-20Co合金由HCP相和立方相组成。Mg-Zn-Fe-Cu-Co的物理力学性能受基体合金中镁含量的影响。孔隙的存在表明压实和烧结过程不完全。合金的中等硬度在286.06 HV-80.98 HV之间，而合金的密度在3.057 g.cm-3到1.71 g.cm-3之间相对适中。固溶体和金属间沉淀强化被认为是合金的主要强化机制。结果表明，高熵是一种很有前途的镁合金加工方法。化学成分为20Mg-20Zn-20Fe-20Cu-20Co的合金具有最佳的机械性能，满足高熵合金作为输尿管植入物应用候选者的最低要求。

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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来源期刊

Metalurgija 工程技术-冶金工程

CiteScore

1.20

自引率

33.30%

发文量

审稿时长

4-8 weeks

期刊介绍： The journal Metalurgija is primary scientific periodical that publishes scientific papers (original papers, preliminary notes, reviewed papers) as well as professional papers from the area of basic, applicable and developing researching in metallurgy and boundary metallurgy areas (physics, chemistry, mechanical engineering). These papers relate to processing ferrous and non-ferrous metallurgy, treating investigating as well as testing of raw materials, semi products and products, especially in the area of improving new materials and possibilities of their implementation. The journal is the only national periodical of this kind in the Republic of Croatia and covers the scientific field of metallurgy, especially: physical metallurgy and materials; process metailurgy, (ferrous and non-ferrous); mechanical metallurgy (processing, power , etc.); related (adjoing) branches: mechanlcal engineering, chemistry, physics etc.