The Investigation of the Fracture Behavior of a Chinese 9% Cr Steel Welded Joint under Creep-Fatigue Interactive Loading

To understand the premature-fracture mechanisms of long-term service damage of an advanced alloy’s (Chinese P92 steel) welded joint, the creep-fatigue (CF) experiments with holding times of 30, 120, 300, 600 and 900 s were individually performed at 923 K. The cyclic softening, inelastic-strain amplitudes and stress-relaxation behaviors were compared between welded and base-metal (BM) specimens. From the results, the failure stage of the welded specimens occupies 45% of the lifetime fraction, while it only takes up 20% of the lifetime fraction in BM specimens with short holding times (30 and 120 s). Furthermore, only two softening stages were observed for both kinds of CF specimens with long holding times. The absence of a third softening stage in longer-held specimens indicates that the processes of macroscopic-crack initiation, propagation and rupture were accelerated. Based on the observation of the fracture surfaces, the fracture mechanism shifted from fatigue-dominated damage to creep-fatigue interaction when the holding period was increased.

[1]  Zengliang Gao,et al.  Nanoindentation Characterization of Creep-fatigue Interaction on Local Creep Behavior of P92 Steel Welded Joint , 2021, Chinese Journal of Mechanical Engineering.

[2]  Zengliang Gao,et al.  Probing strain rate effect on the creep–fatigue fracture mechanism of 9%Cr steel‐welded joint via nanoindentation characterization , 2021, Fatigue & Fracture of Engineering Materials & Structures.

[3]  S. Goyal,et al.  Studies on creep-fatigue interaction behavior of Grade 92 steel and its weld joints , 2021 .

[4]  Zengliang Gao,et al.  The effects of tensile and compressive dwells on creep-fatigue behavior and fracture mechanism in welded joint of P92 steel , 2021, Materials Science and Engineering: A.

[5]  Zengliang Gao,et al.  The effects of prior creep–fatigue on the strain rate sensitivity of a P92 welded joint , 2021, Journal of Materials Science.

[6]  Zengliang Gao,et al.  On the microstructural evolution and room‐temperature creep behaviour of 9%Cr steel weld joint under prior creep–fatigue interaction , 2020 .

[7]  H. Jing,et al.  Analysis on stress‐strain behavior and life prediction of P92 steel under creep‐fatigue interaction conditions , 2020 .

[8]  Xiaowei Wang,et al.  Remaining creep properties and fracture behaviour of P92 steel welded joint under prior low cycle fatigue loading , 2020 .

[9]  Zengliang Gao,et al.  Nanoindentation investigation on the creep behavior of P92 steel weld joint after creep-fatigue loading , 2020 .

[10]  Guo-Dong Zhang,et al.  Thermal-mechanical fatigue behaviour and life prediction of P92 steel, including average temperature and dwell effects , 2020 .

[11]  Wei Zhang,et al.  Evaluation of the effect of various prior creep-fatigue interaction damages on subsequent tensile and creep properties of 9%Cr steel , 2019, International Journal of Fatigue.

[12]  Wei Zhang,et al.  A New Empirical Life Prediction Model for 9–12%Cr Steels under Low Cycle Fatigue and Creep Fatigue Interaction Loadings , 2019, Metals.

[13]  Xiaowei Wang,et al.  Experimental and numerical characterization of low cycle fatigue and creep fatigue behaviour of P92 steel welded joint , 2018 .

[14]  Pradeep Kumar,et al.  Microstructure-based assessment of creep rupture behaviour of cast-forged P91 steel , 2017 .

[15]  Shun-Peng Zhu,et al.  A modified strain energy density exhaustion model for creep–fatigue life prediction , 2016 .

[16]  P. K. Ray,et al.  Designing P92 grade martensitic steel header pipes against creep–fatigue interaction loading condition: Damage micromechanisms , 2015 .

[17]  Fu-Zhen Xuan,et al.  Creep–fatigue endurance of 304 stainless steels , 2014 .

[18]  A. Shan,et al.  Effect of Mo Addition on Strength of Fire-Resistant Steel at Elevated Temperature , 2014, Journal of Materials Engineering and Performance.