High temperature fatigue creep behavior and life prediction of 316L stainless steel under 2-step load

Chin J Mater Res

2009, Vol. 23

Issue (5): 541-545 DOI:

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High temperature fatigue creep behavior and life prediction of 316L stainless steel under 2-step load

DONG Jie ^1;2; CHEN Xuedong¹; FAN Zhichao¹; JIANG Huifeng ^1;2; JIANG Heng¹; LU Shouxiang²

1.National Technology Research Center on Pressure Vessel and Pipeline Safety Engineering of Hefei General Machinery Research Institute; Hefei 230031
2.Department of Safety Science and Engineering; University of Science and Technology of China; Hefei 230027

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DONG Jie CHEN Xuedong FAN Zhichao JIANG Huifeng JIANG Heng LU Shouxiang. High temperature fatigue creep behavior and life prediction of 316L stainless steel under 2-step load. Chin J Mater Res, 2009, 23(5): 541-545.

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Abstract

High temperature fatigue creep test of 316L stainless steel under 1-step and 2-step load was conducted, the influence of the load history on material behavior was investigated emphatically. On the basis of the uniform fatigue creep damage evolution model, the nonlinear damage evolution curves of 316L steel under 1-step load at high temperature were obtained. A modified failure rule coupled with the load history effect under multi-step load was proposed. High temperature 316L steel fatigue creep life under 2-step load was predicted by the failure rule and the nonlinear damage model. The predicted results were in good agreement with the experimental ones.

Key words: foundational discipline in materials science life prediction failure rule fatigue creep load history

Received: 28 November 2008

ZTFLH:

TG113

Fund:

Supported by the National Great Project of Scientific and Technical Supporting Programs of China during the 11th Five-year Plan No.2006BAK02B02-02 and Natural Science Foundation of Anhui Province No.070415223.

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	DONG Jie-
	CHEN Hua-Dong
	FAN Zhi-Tiao
	JIANG Hui-Feng
	JIANG Heng
	LU Shou-Xiang

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https://www.cjmr.org/EN/ OR https://www.cjmr.org/EN/Y2009/V23/I5/541

1 CHEN Nianjin, GAO Zengliang, LEI Yuebao, Studies on the law of fatigue and creep for 316L stainless steel at elevated temperature, Pressure Vessel Technology, 23(6),6(2006)
(陈年金, 高增粱, 雷月葆, 316L钢高温疲劳蠕变规律研究, 压力容器, 23(6), 6(2006))
2 L.Zrnik, J.Semenak, V.Vrchovinsky, etc, Influence of cycling frequency on cyclic creep characteristics of nickel base single-crystal superalloy, Material Science and Engineering A, 319-321, 637(2001)
3 Z.C.Fan, X.D.Chen, L.Chen, etc, Fatigue-creep behavior of 1.25Cr0.5Mo steel at high temperature and its life prediction, International Journal of Fatigue, 29(6), 1174(2007)
4 JIANG Jialing, CHEN Ling, FAN Zhichao, Discussion of life prediction for fatigue-creep interaction, Chinese Journal of Materials Research, 21(5), 537(2007)
(蒋家羚, 陈凌, 范志超等, 疲劳－蠕变交互作用的寿命预测探讨, 材料研究学报, 21(5), 537(2007))
5 T.Goswami, Low cycle fatigue life prediction-a new model, International Journal of Fatigue, 19(2),109(1997)
6 YANG Tiecheng, CHEN Ling, FAN Zhichao, Life prediction for fatigue-creep interaction of 1.25Cr0.5Mo steel at elevated temperature, Pressure Vessel Technology, 22(9), 8(2005)
(杨铁成, 陈凌, 范志超, 1.25Cr0.5Mo钢高温疲劳蠕变交互作用的寿命预测, 压力容器, 22(9), 8(2005))
7 A.Fatemi, L.Yang, Cumulative fatigue damage and life prediction theories: a survey of the state of the art for homogeneous materials, International Journal of Fatigue, 20(1), 9(1998)
8 X.L.Zheng, Overload effects on fatigue behaviour and life prediction of low-carbon steels, International Journal of Fatigue, 17(5), 331(1995)
9 R.Kumar, A.Kumar, K.Singh, Effect of rest time after application of single overload cycle on fatigue life, Engineering Fracture Mechanics, 54(1), 147(1996)
10 M.Walter, J.Aktaa, M.Lerch, Failure behaviour of EUROFER 97 in the low-cycle fatigue region under multistep loading, International Journal of Fatigue, 30(3), 568(2008)
11 S.G.Hong, S.B.Lee, T.S.Byun, Temperature effect on the low-cycle fatigue behavior of type 316L stainless steel: Cyclic non-stabilization and an invariable fatigue parameter, Material Science and Engineering A, 457(1-2), 139(2007)
12 GUO Yangbo, TANG Zhiping, A Dislocation-mechanicsbased constitutive model for dynamic strain aging, Acta Mechanical Solid Sinica, 23(3), 251(2002)
(郭扬波, 唐志平, 一种基于位错机制的动态应变时效模型, 固体力学学报, 23(3), 251(2002))
13 S.G.Hong, K.O.Lee, S.B.Lee, Dynamic strain aging effect on the fatigue resistance of type 316L stainless steel, International Journal of Fatigue, 27(10-12), 1420(2005)
14 S.G.Hong, S.B.Lee, Dynamic strain aging under tensile and LCF loading conditions, and their comparison in cold worked 316L stainless steel, Journal of Nuclear Materials, 328(2-3), 232(2004)
15 T.W.Kim, D.H.Kang, J.T.Yeom, Continuum damage mechanics-based creep fatigue-interacted life prediction of nickel-based superalloy at high temperature, Scripta Materialia, 57(12), 1149(2007)
16 CHEN Zhiping, JIANG Jialing, CHEN Ling, Research on fatigue-creep interaction damage of steel 1.25Cr0.5Mo, Acta Metallurgica Sinica, 43(6), 637(2007)
(陈志平, 蒋家羚, 陈凌, 1.25Cr0.5Mo钢疲劳－蠕变交互作用的损伤研究, 金属学报, 43(6), 637(2007))

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