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A multi-barrier model assisted CAFE method for predicting ductile-to-brittle transition with application to a low-carbon ultrahigh-strength steel

A multi-barrier model assisted CAFE method for predicting ductile-to-brittle transition with application to a low-carbon ultrahigh-strength steel

Kategori
Vitenskapelig artikkel
Sammendrag
The conventional micromechanical approaches today are still not able to properly predict the ductile-to-brittle transition (DBT) of steels because of their inability to consider the co-operating ductile fracture and cleavage mechanisms in the transition region, and simultaneously to incorporate the inherent complexity of microstructures. In this study, a complete methodology with coupled cellular automata finite element method (CAFE) and multi-barrier microcrack propagation models is presented to advance the prediction of DBT. The methodology contains three key elements: (i) a multiscale CAFE modelling approach to realize the competition between ductile damage and cleavage fracture and embrace the probabilistic nature of microstructures, (ii) a continuum approach to estimate the effective surface energy for a microcrack to penetrate over particle/matrix interface, and (iii) a method to calculate the effective surface energy for the microcrack to propagate across grain boundaries. The prediction of DBT therefore needs only (1) the stress-strain curves tested at different temperatures, (2) the activation energy for DBT, (3) the ratio between the size of cleavage facets and cleavage-initiating defects, and (4) key statistical distributions of the given microstructures. The proposed methodology can accurately reproduce the experimental DBT curve of a low carbon ultrahigh-strength steel.
Oppdragsgiver
  • Research Council of Norway (RCN) / 228513
Språk
Engelsk
Forfatter(e)
  • Yang Li
  • Sakari Pallaspuro
  • Xiaobo Ren
  • Jianying He
  • Jukka Kömi
  • Zhiliang Zhang
Institusjon(er)
  • Norges teknisk-naturvitenskapelige universitet
  • Kina
  • Oulun yliopisto
  • SINTEF Industri / Materialer og nanoteknologi