On microstructural and mechanical properties of 21-4-N nitronic steel joint developed using microwave energy

Journal of Micromanufacturing Pub Date : 2021-07-27 DOI:10.1177/25165984211033427

S. Bhandari, Shivani Gupta, R. Mishra, A. Sharma, N. Arora

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引用次数: 2

Abstract

In the current experimental work, an effort has been made to explore the feasibility of fusion joints of 21-4-N nitronic steel employing microwave heating. These fusion joints were developed inside a domestic microwave applicator operating at 900 W. Microwave energy was used to fabricate the joints in hybrid heating mode by converting electromagnetic energy into heat at 2.45 GHz. Charcoal and SiC plates were used as susceptor and separator, respectively, and nickel powder was used as the interface material. The developed joints were characterized for their microstructural and mechanical properties. The microstructures indicate a complete fusion of nickel interfacing powder with the faying surfaces. XRD results show the formation of metallic nitrides and carbide phases (Cr2N, Fe3N, and Fe2C) and the FeNi phase at the weld zone. Furthermore, the observed average tensile strength of the fusion joints was approximately 61% of base metal. The reduction in the stress and elongation compared to the base metal were 38.67% and 12.68%, respectively. The average microhardness of the microwave joints was monitored as 407 ± 69.27 HV. The results indicate the feasibility of fusion joints of nitronic steel using microwave energy.

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微波能制备21-4-N氮化钢接头的组织与力学性能

在目前的实验工作中，探讨了采用微波加热的方法熔接21-4-N氮钢的可行性。这些融合接头是在900w的家用微波应用器中开发的。利用微波能量将电磁能量转换为2.45 GHz的热量，以混合加热方式制作接头。采用炭片和碳化硅片分别作为电极和分离器，镍粉作为界面材料。对发育的接头进行了显微组织和力学性能表征。显微组织表明镍界面粉与镀层表面完全融合。XRD结果表明，焊缝区形成了金属氮化物、碳化物相(Cr2N、Fe3N、Fe2C)和FeNi相。此外，观察到的熔合接头的平均抗拉强度约为母材的61%。与母材相比，合金的应力和伸长率分别降低了38.67%和12.68%。微波接头的平均显微硬度为407±69.27 HV。结果表明，利用微波能量熔接氮钢接头是可行的。

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 Micromanufacturing

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