Microstructural evolution and constitutive models to predict hot deformation behaviors of a nickel-based superalloy
Created by W.Langdon from
gp-bibliography.bib Revision:1.8051
- @Article{Lin:2017:Vacuum,
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author = "Y. C. Lin and Fu-Qi Nong and Xiao-Min Chen and
Dong-Dong Chen and Ming-Song Chen",
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title = "Microstructural evolution and constitutive models to
predict hot deformation behaviors of a nickel-based
superalloy",
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journal = "Vacuum",
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volume = "137",
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pages = "104--114",
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year = "2017",
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ISSN = "0042-207X",
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DOI = "
doi:10.1016/j.vacuum.2016.12.022",
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URL = "
http://www.sciencedirect.com/science/article/pii/S0042207X16308041",
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abstract = "To investigate the hot deformation behaviors of a
nickel-based superalloy, the hot compressive tests are
conducted at the deformation temperature range of
920-1040 degreeC and strain rate range of 0.001-1s-1.
It is found that the effects of strain rate and
deformation temperature on the grain boundary maps are
significant. An almost competed dynamic
recrystallization (DRX) microstructure occurs at
relatively low strain rates. However, the increased
strain rate easily leads to the uneven microstructures.
The DRX degree notably increases with the increase of
deformation temperature, because the high temperature
enhances the grain boundary migration mobility and
facilitates the nucleation and growth of DRX grains.
Based on the experimental results, multi-gene genetic
programming (MGGP), artificial neural network (ANN) and
Arrhenius type phenomenological models are established
to predict the flow stress. Due to the obvious
over-fitting problem of MGGP model, a Hannan-Quinn
information criterion based MGGP (HQC-MGGP) approach is
proposed. The performances of MGGP, HQC-MGGP, ANN and
phenomenological models are compared. It is found that
HQC-MGGP model has the best performance to predict the
flow stress under the experimental conditions.
Therefore, HQC-MGGP model is accurate and reliable in
describing the hot deformation behaviors of the studied
nickel-based superalloy.",
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keywords = "genetic algorithms, genetic programming, Alloy, Hot
deformation, Grain boundary map, Constitutive model",
- }
Genetic Programming entries for
Y C Lin
Fu-Qi Nong
Xiao-Min Chen
Dong-Dong Chen
Ming-Song Chen
Citations
