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Characterization of Early Fatigue Microstructure in AISI 321 Steel Using Eddy Current Non-destructive Methodology 被引量:1

Characterization of Early Fatigue Microstructure in AISI 321 Steel Using Eddy Current Non-destructive Methodology
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摘要 Accumulative damage during early stage of fatigue in AISI 321 steel was investigated by eddy current test, atomic force microscopy, X-ray diffraction and transmission electron microscopy. Surface slip, dislocation, and strain-induced martensite were determined as the main damage types. Moreover, damage during the fatigue was found to be increased with the increasing fatigue cycles and load amplitude. The contribution of strain-induced martensite to the total eddy current amplitude (V) was enhanced with the increase in its volume fraction. Finally, a linear relationship between V I~, and the height of surface slip was established. Accumulative damage during early stage of fatigue in AISI 321 steel was investigated by eddy current test, atomic force microscopy, X-ray diffraction and transmission electron microscopy. Surface slip, dislocation, and strain-induced martensite were determined as the main damage types. Moreover, damage during the fatigue was found to be increased with the increasing fatigue cycles and load amplitude. The contribution of strain-induced martensite to the total eddy current amplitude (V) was enhanced with the increase in its volume fraction. Finally, a linear relationship between V I~, and the height of surface slip was established.
作者 LIU Kunpeng ZHAO Zihua ZHANG Zheng
机构地区 Key Laboratory of Aerospace Materials and Performance
出处 《Journal of Wuhan University of Technology(Materials Science)》 SCIE EI CAS 2013年第6期1201-1206,共6页 武汉理工大学学报(材料科学英文版)
关键词 eddy current early stage of fatigue surface slip strain-induced martensite DISLOCATION eddy current early stage of fatigue surface slip strain-induced martensite dislocation
分类号 TG142.71 [金属学及工艺—金属材料]
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参考文献14

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Journal of Wuhan University of Technology(Materials Science)
2013年 第6期

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