RT info:eu-repo/semantics/article T1 Modelling of fatigue microfracture in porous sintered steel using a phase-field method A1 Tomić, Zoran A1 Jarak, Tomislav A1 Lesičar, Tomislav A1 Gubeljak, Nenad A1 Tonković, Zdenko K1 Metals K1 Metallic Materials K1 Metales - Materiales K1 Materials science K1 Ciencia de los materiales K1 Microcracks K1 Fatigue K1 Materiales - Fatiga K1 Metales - Fatiga K1 Phase field method K1 Porosity K1 Porosidad K1 2303.18 Metales K1 3312 Tecnología de Materiales AB Porosity in sintered materials negatively affects its fatigue properties. In investigating its influence, the application of numerical simulations reduces experimental testing, but they are computationally very expensive. In this work, the application of a relatively simple numerical phase-field (PF) model for fatigue fracture is proposed for estimation of the fatigue life of sintered steels by analysis of microcrack evolution. A model for brittle fracture and a new cycle skipping algorithm are used to reduce computational costs. A multiphase sintered steel, consisting of bainite and ferrite, is examined. Detailed finite element models of the microstructure are generated from high-resolution metallography images. Microstructural elastic material parameters are obtained using instrumented indentation, while fracture model parameters are estimated from experimental S–N curves. Numerical results obtained for monotonous and fatigue fracture are compared with data from experimental measurements. The proposed methodology is able to capture some important fracture phenomena in the considered material, such as the initiation of the first damage in the microstructure, the forming of larger cracks at the macroscopic level, and the total life in a high cycle fatigue regime. However, due to the adopted simplifications, the model is not suitable for predicting accurate and realistic crack patterns of microcracks. PB MDPI SN 1996-1944 YR 2023 FD 2023 LK https://uvadoc.uva.es/handle/10324/65822 UL https://uvadoc.uva.es/handle/10324/65822 LA eng NO Materials, 2023, Vol. 16, Nº. 11, 4174 NO Producción Científica DS UVaDOC RD 18-nov-2024