Thermal fatigue behavior of K465 superalloy 被引量：15

Thermal fatigue behavior of K465 superalloy

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摘要 The thermal fatigue behavior of K465 superalloy was investigated at the peak temperature of 1050℃. By scanning electron microscopy （SEM） and optical microscopy, the main crack length was observed and measured. The initiation sites of the tested alloys are different in as-cast （named as K465） and solution heat treatment （named as SK465） conditions. In K465 alloy, most thermal fatigue cracks nucleate at （Nb,W,Ti）C carbides. In SK465 alloy, thermal fatigue cracks initiate in interdendritic regions, MC-type carbides and some interfaces. Thermal fatigue cracks propagate in transdendritic mode, and M6C-type carbides could retard thermal fatigue crack growth for SK465 superalloy. The thermal fatigue behavior of K465 superalloy was investigated at the peak temperature of 1050℃. By scanning electron microscopy （SEM） and optical microscopy, the main crack length was observed and measured. The initiation sites of the tested alloys are different in as-cast （named as K465） and solution heat treatment （named as SK465） conditions. In K465 alloy, most thermal fatigue cracks nucleate at （Nb,W,Ti）C carbides. In SK465 alloy, thermal fatigue cracks initiate in interdendritic regions, MC-type carbides and some interfaces. Thermal fatigue cracks propagate in transdendritic mode, and M6C-type carbides could retard thermal fatigue crack growth for SK465 superalloy.

作者 YANG Jinxia ZHENG Qi SUN Xiaofeng GUAN Hengrong HU Zhuangqi

机构地区 Institute of Metal Research

出处《Rare Metals》 SCIE EI CAS CSCD 2006年第3期202-209,共8页 稀有金属（英文版）

关键词 K465 superalloy thermal fatigue crack initiation and growth carbides K465 superalloy thermal fatigue crack initiation and growth carbides

分类号 TG146.261 [金属学及工艺—金属材料] TG132.33 [一般工业技术—材料科学与工程]

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Thermal fatigue behavior of K465 superalloy 被引量：15

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