用不同方法生产的 316L 钢的机械性能和微观结构

IF 0.9 4区 材料科学 Q3 MATERIALS SCIENCE, CERAMICS
S. V. Adjamsky, G. A. Kononenko, R. V. Podolskyi, O. A. Safronova, O. A. Shpak
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引用次数: 0

摘要

316L 不锈钢符合所有健康、强度和质量标准,是制造医疗设备不可替代的材料。这项研究的重点是 316L 奥氏体不锈钢,采用符合 ASTM A276/A276M-17 条件 A 的传统技术(样品经轧制并在 1050°C 下水冷退火)和选择性激光熔化(SLM)技术(按原样打印的起始样品)制造。与传统制造技术不同,选择性激光熔融技术提供了更大的设计自由度。使用 AxioMat 200M 光学显微镜在不同照明模式下分析微观结构,并使用 Kalling 和 Marble 试剂揭示结构。传统方法生产的 316L 钢主要由奥氏体组成(显微硬度为 239 kg/mm2),测试样品的横截面晶粒具有很大的异质性。在单个晶粒(显微硬度为 260-286 kg/mm2)和单向疏松结构(显微硬度为 317-328 kg/mm2)区域观察到孪晶和非典型多向致密针状结构。用 SLM 技术生产的 316L 钢的微观结构主要由奥氏体组成(显微硬度为 268 kg/mm2)。马勃试剂显示了初级奥氏体晶粒的边界,并确定了熔池的弧形结构。卡林试剂显示了非典型的多向取向晶内亚结构,主要位于上一层轨道重叠区域的下一层轨道顶部之间(纵向显微硬度为 239-251 kg/mm2,横截面显微硬度为 286-317 kg/mm2)。使用微分干涉对比显微镜可发现细长的柱状晶粒。传统技术生产的钢材样品的平均极限强度比 SLM 生产的样品高 4.63%,屈服强度高 1.53%,相对伸长率高 8.27%,相对收缩率高 18.36%。SLM 钢材的性能水平较低,其数值的分布范围较大,这是由于存在细长晶粒和相对于堆积方向的各向异性。SLM 钢在起始状态下显示的实际性能水平符合法规要求。
本文章由计算机程序翻译,如有差异,请以英文原文为准。

Mechanical Properties and Microstructure of the 316L Steel Produced by Different Methods

Mechanical Properties and Microstructure of the 316L Steel Produced by Different Methods

The 316L stainless steel meets all health, strength, and quality standards and is an irreplaceable material in the manufacture of medical equipment. The study focused on the 316L austenitic stainless steel, manufactured with the conventional technique in accordance with ASTM A276/A276M–17 Condition A (samples rolled and annealed at 1050°C with water cooling) and with the selective laser melting (SLM) technique (as-printed starting samples). Unlike conventional manufacturing techniques, SLM offers significantly greater design freedom. An AxioMat 200M optical microscope was employed to analyze the microstructure in different lighting modes, and Kalling’s and Marble’s reagents were used to reveal the structure. The 316L steel produced conventionally mainly consisted of austenite (microhardness of 239 kg/mm2), and substantial cross- sectional grain heterogeneity was established in the test sample. Twins and an atypical multidirectionally oriented dense acicular structure in the area of individual grains (microhardness of 260‒286 kg/mm2) and a unidirectional loose structure (microhardness of 317‒328 kg/mm2) were observed. The microstructure of the 316L steel produced with the SLM technique mainly consisted of austenite (microhardness of 268 kg/mm2). The boundaries of the primary austenite grains were revealed with Marble’s reagent, and arc-shaped structures of the melt bath were established. Kalling’s reagent revealed an atypical multidirectionally oriented intragranular substructure, located primarily between the tops of next-layer tracks in areas where previous-layer tracks overlapped (longitudinal microhardness of 239–251 kg/mm2 and cross-sectional microhardness of 286–317 kg/mm2). Elongated columnar grains were found using differential interference contrast microscopy. The average ultimate strength of the steel samples produced with the conventional technique was higher than that of the samples produced with SLM by 4.63%, yield strength by 1.53%, relative elongation by 8.27%, and relative contraction by 18.36%. The lower level of properties and greater spread of their values for the SLM steel were due to the presence of elongated grains and anisotropy relative to the buildup direction. The actual level of properties shown by the SLM steel in the starting state meets the regulatory requirements.

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来源期刊
Powder Metallurgy and Metal Ceramics
Powder Metallurgy and Metal Ceramics 工程技术-材料科学:硅酸盐
CiteScore
1.90
自引率
20.00%
发文量
43
审稿时长
6-12 weeks
期刊介绍: Powder Metallurgy and Metal Ceramics covers topics of the theory, manufacturing technology, and properties of powder; technology of forming processes; the technology of sintering, heat treatment, and thermo-chemical treatment; properties of sintered materials; and testing methods.
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