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New approaches for a reliable fatigue life prediction of powder metallurgy components using machine learning

Dominik Sebastian Leininger, Felix-Christian Reissner, J. Baumgärtner

2022Fatigue & Fracture of Engineering Materials & Structures16 citationsDOIOpen Access PDF

Abstract

Abstract Up to now, no consistent fatigue assessment approach of powder metallurgy (PM) components is available. For some materials and for some parameters, such as the density, a relationship to the fatigue strength is known; however, for other materials, such relationships are unknown. Based on an extensive data set with 828 test series, the present work addresses this problem by conceiving and applying five machine learning (ML)‐based approaches to increase the accuracy of the prediction of the fatigue life as well as to predict the scatter of unknown data as precisely as possible. With the elaborated procedure, on the one hand, a scatter range of can be achieved on completely unknown data. On the other hand, by using a newly defined loss function, the standard deviation of unknown data can be predicted very accurately. The findings provide the basis for further research on cost and efficiency optimized design of PM components through better estimation of fatigue life.

Topics & Concepts

Powder metallurgyRange (aeronautics)Set (abstract data type)Standard deviationWork (physics)Experimental dataBasis (linear algebra)Test dataComputer scienceData setFunction (biology)Reliability engineeringMachine learningMaterials scienceArtificial intelligenceEngineeringMechanical engineeringMathematicsMetallurgyStatisticsMicrostructureComposite materialBiologyEvolutionary biologyGeometryProgramming languagePowder Metallurgy Techniques and MaterialsMetallurgy and Material FormingFatigue and fracture mechanics