Post-localized blast experimental investigation of mechanical properties and microstructural evolutions in austenitic stainless steel 316L

IF 3 Q2 MATERIALS SCIENCE, MULTIDISCIPLINARY Materialia Pub Date : 2024-10-15 DOI:10.1016/j.mtla.2024.102263
S. Gholizadeh , S Chung Kim Yuen , S.L. George
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Abstract

Mechanical loading causes material deformation, resulting in changes in mechanical properties due to microstructural alterations such as the multiplication of dislocations and evolution of grain morphology. Blast loading, a condition where materials deform at high strain rates, results in significant plastic deformation. This rapid deformation induces intense mechanical stresses, causing complex microstructural changes that influence the mechanical behavior and performance of the materials. Consequently, designing structures to withstand blast loading requires understanding the relationship between microstructure and property evolution. As the primary objective of this study, post-localized blast experiments have been conducted to elucidate the variability in microstructural response of Austenitic stainless steel (ASS) 316 L, characterized by its face-centered cubic crystal structure. Localized blast loads were applied to square test plates, 2 mm thick, with a circular exposed area of 106 mm in diameter. Quantitative mechanical property data from key zones within the deformed dome were determined through using a novel micro-tensile testing approach and nanoindentation tests. Electron backscatter diffraction (EBSD) in scanning electron microscopy (SEM) technique was employed to characterize the microstructural changes in the selected samples. The results revealed that blast loading induced complex mechanical and microstructural changes in ASS 316 L, including enhanced material strength, reduced ductility, and significant alterations in grain orientation and misorientation distributions. The materials underwent significant strain hardening due to the increased stress and deformation, resulting in a more resistant to plastic deformation and the greatest internal strain accumulations. Texture analysis underscored the influence of deformation geometry, with Goss and Copper emerging as predominant texture components.

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奥氏体不锈钢 316L 机械性能和微结构演变的局部爆破后实验研究
机械加载会导致材料变形,从而引起微观结构的改变,如位错的增加和晶粒形态的演变,从而导致机械性能的变化。爆破加载是一种材料以高应变率变形的条件,会导致显著的塑性变形。这种快速变形会引起强烈的机械应力,导致复杂的微观结构变化,从而影响材料的机械行为和性能。因此,要设计出能承受爆炸荷载的结构,就必须了解微观结构与性能演变之间的关系。本研究的主要目标是进行局部爆炸后实验,以阐明奥氏体不锈钢 (ASS) 316 L 微结构响应的变化,其特点是面心立方晶体结构。对厚度为 2 毫米、圆形暴露区直径为 106 毫米的方形测试板施加了局部爆炸载荷。通过使用新型微拉伸测试方法和纳米压痕测试,确定了变形穹顶内关键区域的定量机械性能数据。扫描电子显微镜(SEM)技术中的电子反向散射衍射(EBSD)被用来表征所选样品的微观结构变化。结果表明,爆炸加载导致 ASS 316 L 发生了复杂的机械和微观结构变化,包括材料强度提高、延展性降低以及晶粒取向和错取向分布的显著改变。由于应力和变形的增加,材料发生了明显的应变硬化,从而产生了更强的抗塑性变形能力和最大的内部应变累积。纹理分析强调了变形几何形状的影响,戈斯和铜成为主要的纹理成分。
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来源期刊
Materialia
Materialia MATERIALS SCIENCE, MULTIDISCIPLINARY-
CiteScore
6.40
自引率
2.90%
发文量
345
审稿时长
36 days
期刊介绍: Materialia is a multidisciplinary journal of materials science and engineering that publishes original peer-reviewed research articles. Articles in Materialia advance the understanding of the relationship between processing, structure, property, and function of materials. Materialia publishes full-length research articles, review articles, and letters (short communications). In addition to receiving direct submissions, Materialia also accepts transfers from Acta Materialia, Inc. partner journals. Materialia offers authors the choice to publish on an open access model (with author fee), or on a subscription model (with no author fee).
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