Parameters Identification of High Temperature Damage Model of X12 Alloy Steel for Ultra-Supercritical Rotor Using Inverse Optimization Technique

X12 alloy steel is a new generation material for manufacturing ultra-supercritical generator rotors. Cracks will appear on the forgings during the forging process and the rotors will be scrapped in serious cases. To optimize the forging process of the rotor and avoid the occurrence of crack defects...

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Bibliographic Details
Published in:Materials 2021-02, Vol.14 (3), p.695
Main Authors: Chen, Xuewen, Du, Kexue, Du, Yuqing, Lian, Tingting, Liu, Jiqi, Bai, Rongren, Li, Zhipeng, Yang, Yisi, Jung, Dongwon
Format: Article
Language:English
Subjects:
Alloy steels
Axial stress
Cracks
Damage assessment
Deformation
Finite element method
Forging
Forgings
High temperature
Hot forming
Methods
Model accuracy
Optimization
Optimization algorithms
Optimization techniques
Parameter identification
Phase transitions
Rotors
Simulation
Steam pressure
Strain rate
Temperature effects
Tensile tests
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Summary:X12 alloy steel is a new generation material for manufacturing ultra-supercritical generator rotors. Cracks will appear on the forgings during the forging process and the rotors will be scrapped in serious cases. To optimize the forging process of the rotor and avoid the occurrence of crack defects in the hot forming process, based on Oyane damage model, a high temperature damage model of X12 alloy steel was proposed by introducing the influences of temperature and strain rate on the damage evolution. A reverse analysis method was proposed to determine the critical damage value of Oyane damage model by comparing experimental and simulated fracture displacement in the tensile tests. Then, the critical damage value was determined as a function of temperature and strain rate. The high temperature damage model was combined to the commercial finite element software FORGE to simulate the high temperature tensile test. The accuracy of the damage model was verified by comparing the difference of the fracture displacement between simulated and experimental samples. Additionally, as stress triaxiality is a significant factor influencing the damage behavior of ductile materials, the effects of temperature and strain rate on the stress triaxiality of X12 alloy steel was analyzed by simulating the high temperature tensile process, and the damage mechanism of X12 alloy steel under high stress triaxiality was analyzed by SEM (Scanning Electron Microscope).
ISSN:1996-1944
1996-1944
DOI:10.3390/ma14030695