Nondestructive In-situ Strength Analysis of High-strength Metal with Nano-size Microstructure

2007 International Symposium on Micro-NanoMechatronics and Human Science Pub Date : 2007-11-01 DOI:10.1109/MHS.2007.4420903

Y. Kojima, H. Kimura, K. Tsuji, Y. Akiniwa, K. Tanka

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Abstract

In-situ neutron diffraction measurement was conducted to investigate the plastic deformation and fatigue damage behavior of ultrafine-grained high-strength Cu processed by equal channel angular pressing, ECAP. The experiments were conducted on the ultrafine-grained samples, as well as large-grained counterparts, under tensile and fatigue loading using RESA of Japan Atomic Energy Agency. The diffraction profiles were analyzed in relation with the applied stress, strain and fatigue damage. The result of the large-grained samples shows that the full width at half maximum, FWHM, of the profile from 311 diffraction plane increases with increasing applied stress and that the FWHM remains large even when the sample is unloaded due to accumulated plastic strain. On the other hand, the result of the ultrafine-grained samples shows that the FWHM decreases to the original value upon unloading even after the plastic deformation. The similar results were observed in the process of low-cycle fatigue. The decrease in the FWHM in the ultrafine-grained sample is attributed to the rearrangement of transgranular plastic strain in ultrafine grains.

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具有纳米微观结构的高强度金属的无损原位强度分析

采用原位中子衍射测试方法研究了等径角挤压(ECAP)超细晶高强铜的塑性变形和疲劳损伤行为。利用日本原子能机构的RESA对超细晶和大晶试样进行了拉伸和疲劳载荷试验。分析了衍射曲线与外加应力、应变和疲劳损伤的关系。结果表明，311衍射平面剖面的半最大全宽FWHM随外加应力的增加而增大，即使由于累积的塑性应变而卸载，FWHM仍保持较大。另一方面，超细晶试样的结果表明，即使在塑性变形后卸载后，FWHM也会下降到原始值。在低周疲劳过程中也观察到类似的结果。超细晶试样中FWHM的减小是由于超细晶中穿晶塑性应变的重排所致。

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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2007 International Symposium on Micro-NanoMechatronics and Human Science

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