Assessment of creep-fatigue behavior, deformation mechanisms, and microstructural evolution of alloy 709 under accelerated conditions

Porter T. D.; Findley K. O.; Kaufman M. J.; Wright R. N.

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Assessment of creep-fatigue behavior, deformation mechanisms, and microstructural evolution of alloy 709 under accelerated conditions

机译：评估加速条件下合金709的蠕变疲劳行为，变形机理和微观结构演变

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Alloy 709 is a leading candidate structural material for sodium-cooled fast spectrum reactors (FSR), where creepfatigue is a potential failure mode. Low cycle fatigue (LCF) and creep-fatigue tests with 30 min tensile hold times have been conducted to failure at 550 and 650 degrees C, corresponding to potential service and accelerated test temperatures, respectively. Creep-fatigue life is reduced relative to LCF at both temperatures, though significantly more at 550 degrees C compared to 650 degrees C. Differences in slip behavior, dynamic recovery, precipitate evolution, and strain-aging effects result in less stress relaxation and sustained high tensile stresses in creep-fatigue at 550 degrees C; thus, there is more intergranular damage compared to 650 degrees C.

机译：709合金是钠冷快谱反应堆（FSR）的主要候选结构材料，蠕变疲劳是一种潜在的失效模式。在550和650摄氏度下进行了30分钟拉伸保持时间的低周疲劳（LCF）和蠕变疲劳测试，分别对应于潜在的使用温度和加速的测试温度。在两个温度下，蠕变疲劳寿命均相对于LCF降低，尽管在550°C时与650°C相比，蠕变疲劳寿命显着增加。滑移行为，动态恢复，析出物演化和应变时效效应的差异导致应力松弛减少并持续较高550℃蠕变疲劳中的拉应力；因此，与650摄氏度相比，存在更多的晶间破坏。

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来源
《International Journal of Fatigue 》 |2019年第7期| 205-216| 共12页
作者
Porter T. D.; Findley K. O.; Kaufman M. J.; Wright R. N.;
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作者单位

Colorado Sch Mines, 1500 Illinois St, Golden, CO 80401 USA;

Colorado Sch Mines, 1500 Illinois St, Golden, CO 80401 USA;

Colorado Sch Mines, 1500 Illinois St, Golden, CO 80401 USA;

Idaho Natl Lab, 1955 Fremont,POB 1625, Idaho Falls, ID 83415 USA;

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收录信息美国《科学引文索引》(SCI);美国《工程索引》(EI);
原文格式 PDF
正文语种 eng
中图分类
关键词
Alloy 709; Creep-fatigue; Microstructure evolution; Time-dependent deformation; Dynamic strain aging;

机译：709合金;蠕变疲劳;组织演变;时变;动态应变时效;

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Assessment of creep-fatigue behavior, deformation mechanisms, and microstructural evolution of alloy 709 under accelerated conditions

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