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316L(N) Creep Modeling with Phenomenological Approach and Artificial Intelligence Based Methods

D. Baraldi, Stefan Holmström, Karl-Fredrik Nilsson, Matthias Bruchhausen, Igor Simonovski

2021Metals12 citationsDOIOpen Access PDF

Abstract

A model that describes creep behavior is essential in the design or life assessment of components and systems that operate at high temperatures. Using the RCC-MRx data and the LCSP (logistic creep strain prediction) model, processed design data were generated over the whole creep regime of 316L(N) steel—i.e., primary, secondary, and tertiary creep. The processed design data were used to develop three models with different approaches for the creep rate: a phenomenological approach; an artificial neural network; and an artificial intelligence method based on symbolic regression and genetic programming. It was shown that all three models are capable of describing the true creep rate as a function of true creep strain and true stress over a wide range of engineering stresses and temperatures without the need of additional micro-structural information. Furthermore, the results of finite element simulations reproduce the trends of experimental data from the literature.

Topics & Concepts

CreepGenetic programmingArtificial neural networkPhenomenological modelSymbolic regressionComputer scienceMaterials scienceRange (aeronautics)Experimental dataComponent (thermodynamics)Stress (linguistics)Structural engineeringStrain rateFinite element methodArtificial intelligenceEngineeringThermodynamicsComposite materialMathematicsPhysicsStatisticsLinguisticsPhilosophyHigh Temperature Alloys and CreepMicrostructure and Mechanical Properties of SteelsMetallurgy and Material Forming
316L(N) Creep Modeling with Phenomenological Approach and Artificial Intelligence Based Methods | Litcius