FATIGUE/CREEP INTERACTION FRACTURE MAP AT VARIOUS TEMPERATURES

Acta Metall Sin

1988, Vol. 24

Issue (6): 439-442 DOI:

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FATIGUE/CREEP INTERACTION FRACTURE MAP AT VARIOUS TEMPERATURES

ZHANG Hongxue;XU Zhichao;CHEN Gaoliang Beijing University of Iron and Steel Technology

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ZHANG Hongxue;XU Zhichao;CHEN Gaoliang Beijing University of Iron and Steel Technology. FATIGUE/CREEP INTERACTION FRACTURE MAP AT VARIOUS TEMPERATURES. Acta Metall Sin, 1988, 24(6): 439-442.

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Abstract The relative ratio of fatigue resistance to creep resistance of materialsvaries with test temperature. As the temperature decreases, the creep resistance,since it is a thermal activation process, becomes relatively larger than fatigueresistance. The fatigue damage therefore becomes predominant, and results inexpansion of fatigue fracture region (F region) and shrinkage even complete elimina-tion of creep fracture region (C region). This phenomenon could be understood onthe basis of the integrated model of competitive and eumulative models of fatigue/creep interaction. A material parameters, Ω, can be used to estimate the temperatureat which the creep fracture region is completely depressed.

Key words: GH136 alloy fatigue creep fracture

Received: 18 June 1988

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https://www.ams.org.cn/EN/ OR https://www.ams.org.cn/EN/Y1988/V24/I6/439

1 何庆复.北京钢铁学院博士论文,1985
2 Chen G L, He Q F, Gao L, Zhang S H. In: Solomon H D, Halford G R, Kaisand L R, Leis B N eds., Low Cycle Fatigue, Philadelphia: ASTM, 1988: 531
3 陈国良,航空材料(专刊),1983;3(1) :47
4 陈国良,何庆复,高良,章守华,常逢元,赵亚才.北京钢铁学院学报,1986;(2) :41
5 Klesuil M, Lukas R. Fatigue of Metallic Materials, Amsterdam: Elserier Scientific Publishing Company, 1980: 133z

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