Revealing the microstructural evolution and mechanical response of repaired Fe–Cr–Si based alloy by directed energy deposition

Seung-Chang Han, Yoon-Sun Lee, Ho-Jin Lee, Minki Kim, Tea-Sung Jun
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Abstract

This study investigates the microstructure and mechanical properties of wear-resistant hardfacing structures fabricated on an AISI 1045 carbon steel substrate using a specially designed Fe–Cr based powder for directed energy deposition (DED). Electron backscatter diffraction (EBSD) analysis reveals that the texture predominantly consists of cube rotated {001}<110> and cube {001}<110> textures, in addition to weaker Brass {112}<111> texture components. These textures contribute to the random orientations of martensitic grains and facilitate the tracing of austenite reconstruction. Notably, the as-printed samples exhibited superior yield strength (999.4 ± 86.3 MPa) and ductility (9.6 ± 2.6%) along the build direction (BD), compared to conventional samples, which demonstrated a tensile strength of 790 MPa and ductility of 2%. This improvement is primarily attributed to the hardening effects associated with a low volume fraction of retained austenite and the precipitation of Cr carbides. Comprehensive mechanical response, nanoindentation hardness profile across the interface, and microstructural analyses were conducted to confirm the feasibility of using a Fe-based hardfacing alloy for DED. The findings underscore the outstanding balance of strength and ductility exhibited by as-printed hardfacing alloy, further enhanced by its high printability, highlighting its potential in producing wear-resistant structures for repair applications.
通过定向能沉积揭示修复的铁-铬-硅基合金的微观结构演变和力学响应
本研究使用专门设计的用于定向能沉积 (DED) 的铁铬基粉末,研究了在 AISI 1045 碳钢基材上制造的耐磨硬面结构的微观结构和机械性能。电子反向散射衍射(EBSD)分析表明,除了较弱的黄铜{112}纹理成分外,纹理主要由立方体旋转{001}和立方体{001}纹理组成。这些纹理有助于马氏体晶粒的随机取向,并有助于奥氏体重构的追踪。值得注意的是,与传统样品(抗拉强度为 790 兆帕,延展性为 2%)相比,压印样品沿构建方向(BD)表现出更高的屈服强度(999.4 ± 86.3 兆帕)和延展性(9.6 ± 2.6%)。这种改进主要归因于与低体积分数的残留奥氏体和铬碳化物沉淀相关的硬化效应。为了证实将铁基硬面合金用于 DED 的可行性,我们进行了全面的机械响应、整个界面的纳米压痕硬度曲线和微观结构分析。研究结果强调了印刷硬面合金在强度和延展性之间的出色平衡,其高度的可印刷性进一步增强了这一点,突出了其在生产用于修复应用的耐磨结构方面的潜力。
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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