Stating Failure Modelling Limitations of High Strength Sheets: Implications to Sheet Metal Forming

This article discusses the fracture modelling accuracy of strain-driven ductile fracture models when introducing damage of high strength sheet steel. Numerical modelling of well-known fracture mechanical tests was conducted using a failure and damage model to control damage and fracture evolution. A thorough validation of the simulation results was conducted against results from laboratory testing. Such validations show that the damage and failure model is suited for modelling of material failure and fracture evolution of specimens without damage. However, pre-damaged specimens show less correlation as the damage and failure model over-predicts the displacement at crack initiation with an average of 28%. Consequently, the results in this article show the need for an extension of the damage and failure model that accounts for the fracture mechanisms at the crack tip. Such extension would aid in the improvement of fracture mechanical testing procedures and the modelling of high strength sheet metal manufacturing, as several sheet manufacturing processes are defined by material fracture.

Automated summary

This article discusses the accuracy of fracture modelling with strain-driven ductile fracture models when introducing damage of high strength sheet steel. The study found that pre-damaged specimens showed less correlation and there is a need to extend the model to consider fracture mechanisms at the crack tip.