4D Imaging of Void Nucleation, Growth and Coalescence from Large and Small Inclusions in Steel

AMI: Acta Materialia Pub Date : 2019-11-20 DOI:10.2139/ssrn.3490434

Yi Guo, T. Burnett, S. McDonald, M. Daly, A. Sherry, P. Withers

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引用次数: 2

Abstract

Samples of SA508 grade 3 nuclear pressure vessel ferritic steel were subjected to tensile straining whilst simultaneously imaged in 3D in real time using high resolution, high frame rate time-lapse synchrotron computed tomography (CT). This enabled direct observation of void development from nucleation, through growth to coalescence and final failure validating many inferences made post mortem or by theoretical models, as well as raising new points. The sparse, large inclusions were found to nucleate voids at essentially zero plastic strain (consistent with zero interfacial strength); these became increasingly elongated with straining. In contrast, a high density of small spherical voids were found to nucleate from the sub-micron cementite particles at larger strains (>200%) only in the centre of the necked (high triaxiality) region. An interfacial strength approaching 2100MPa was inferred and soon after their nucleation, these small voids coalesce to form internal microcracks that lead to the final failure of the specimen. Perhaps surprisingly, under these conditions of generally low triaxial constraint the large voids are simply cut across and appear to play no significant role in determining the final failure. The implications of these results are discussed in terms of ductile fracture behaviour and the Gurson model for ductile fracture.

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钢中大小夹杂物空洞形核、生长和聚结的4D成像

采用高分辨率、高帧率延时同步加速器计算机断层扫描(CT)技术，对SA508 3级核压力容器铁素体钢样品进行了拉伸应变处理，同时对样品进行了三维实时成像。这使我们能够直接观察到孔洞从成核、生长到合并和最终破坏的发展过程，从而验证了许多死后或理论模型的推断，并提出了新的观点。稀疏的大夹杂体在塑性应变基本为零时(与界面强度为零一致)形成孔洞;随着用力的增加，它们变得越来越长。相比之下，在较大应变(>200%)下，仅在颈状(高三轴性)区域的中心，亚微米渗碳体颗粒形成高密度的小球形空洞。界面强度接近2100MPa，在成核后不久，这些小孔隙聚集形成内部微裂纹，导致试样最终破坏。也许令人惊讶的是，在通常较低的三轴约束条件下，大的孔洞被简单地切开，似乎在决定最终的破坏中没有重要作用。从韧性断裂行为和韧性断裂的Gurson模型的角度讨论了这些结果的含义。

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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AMI: Acta Materialia

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