Nitrogen Effects in Additively Manufactured Martensitic Stainless Steels: Conventional Thermal Processing and Comparison with Wrought.

IF 2.2 3区 材料科学 Q3 MATERIALS SCIENCE, MULTIDISCIPLINARY Metallurgical and Materials Transactions A-Physical Metallurgy and Materials Science Pub Date : 2020-05-01 DOI:10.1007/s11661-020-05703-6
Eric A Lass, Fan Zhang, Carelyn E Campbell
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引用次数: 21

Abstract

The microstructures of additively manufactured (AM) precipitation-hardenable stainless steels 17-4 and 15-5 were investigated and compared to those of conventionally produced materials. The residual N found in N2-atomized 17-4 powder feedstock is inherited by the additively produced material, and has dramatic effects on phase stability, microstructure, and microstructural evolution. Nitrogen is a known austenite stabilizing element, and the as-built microstructure of AM 17-4 can contain up to 90 pct or more retained austenite, compared to the nearly 100 pct martensite structure of wrought 17-4. Even after homogenization and solutionization heat treatments, AM 17-4 contains 5 to 20 pct retained austenite. In contrast, AM 15-5 and Ar-atomized AM 17-4 contain<5 pct retained austenite in the as-built condition, and this level is further decreased following post-build thermal processing. Computational thermodynamics-based calculations qualitatively describe the observed depression in the martensite start temperature and martensite stability as a function of N-content, but require further refinements to become quantitative. A significant increase in the volume fraction of fine-scale carbide precipitates attributed to the high N-content of AM 17-4 is also hypothesized to give rise to additional activation barriers for the dislocation motion required for martensite nucleation and subsequent growth. An increase in the volume fraction of carbide/nitride precipitates is observed in AM 15-5, although they do not inhibit martensite formation to the extent observed in AM 17-4.

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氮对增材制造马氏体不锈钢的影响:常规热处理及与变形的比较。
研究了增材制造(AM)析出硬化不锈钢17-4和15-5的显微组织,并与常规生产的材料进行了比较。在n2雾化的17-4粉末原料中发现的残余N被增材生产的材料所继承,并对相稳定性、微观结构和微观组织演变产生显著影响。氮是一种已知的奥氏体稳定元素,AM 17-4的构建组织可以包含高达90%或更多的残余奥氏体,而变形后的17-4的马氏体结构几乎为100%。即使经过均质化和固溶热处理,AM 17-4仍含有5%至20%的残余奥氏体。相比之下,AM 15-5和ar雾化AM 17-4含有
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来源期刊
CiteScore
5.30
自引率
7.10%
发文量
322
审稿时长
6 months
期刊介绍: Metallurgical and Materials Transactions A focuses on the latest research in all aspects of physical metallurgy and materials science. It explores relationships among processing, structure, and properties of materials; publishes critically reviewed, original research of archival significance. The journal address the main topics of alloy phases; transformations; transport phenomena; mechanical behavior; physical chemistry; environment; welding & joining; surface treatment; electronic, magnetic & optical material; solidification; materials processing; composite materials; biomaterials; and light metals. MMTA publishes Technical Publications, Communications, Symposia, and more. Published with ASM International, The Materials Information Society and The Minerals, Metals & Materials Society (TMS)
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