Effects of Heat Treatment on Microstructure and Impact Resistance of High Manganese Steels

Journal of Polytechnic Pub Date : 2023-10-30 DOI:10.2339/politeknik.1363853

Hakan Yildirim, M. E. Erdi̇n, Ali Özgedi̇k

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Abstract

High manganese steels are widely used as wear- and impact-resistant materials in many areas, especially in the mining, construction, cement, and metallurgy sectors, where it is extremely important to be able to work safely in high-stress conditions as well as resistance to abrasion under heavy loading conditions thanks to their unique work-hardening performance. At this point, the carbon and manganese ratio of the material has a considerable influence on the microstructure of the cast part after the heat treatment. Therefore, heat treatment conditions have to be determined appropriately depending on the chemical composition of the material. In this study, heat treatment processes were applied to high manganese steel specimens having GX120MnCr18-2 DIN standard at various austenitizing temperatures between 1030~1100 oC. The specimens were examined under an optical microscope and SEM/EDS analyses were performed. Impact resistance and hardness values of the above-mentioned specimens were measured via the tests performed with TS EN ISO 148-1 and TS EN 130 6508-1 standards, respectively. From these investigations, it was determined that the carbide solubility increased as the austenitizing temperature increased while the impact resistance first increased and then decreased.

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热处理对高锰钢微观结构和抗冲击性的影响

高锰钢在许多领域被广泛用作耐磨和抗冲击材料，尤其是在采矿、建筑、水泥和冶金等行业，由于其独特的加工硬化性能，能够在高应力条件下安全工作以及在重负荷条件下的抗磨损性极为重要。此时，材料的碳锰比对热处理后铸件的微观结构有相当大的影响。因此，必须根据材料的化学成分适当确定热处理条件。在本研究中，对符合 GX120MnCr18-2 DIN 标准的高锰钢试样在 1030~1100 oC 的不同奥氏体化温度下进行了热处理。试样在光学显微镜下进行了检查，并进行了扫描电镜/电子显微镜分析。上述试样的抗冲击性和硬度值分别根据 TS EN ISO 148-1 和 TS EN 130 6508-1 标准进行了测试。通过这些研究确定，碳化物溶解度随着奥氏体化温度的升高而增加，而抗冲击性则先增加后降低。

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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Journal of Polytechnic

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