Numerical simulation of dual-phase steel based on real and virtual three-dimensional microstructures

Frederik Scherff,Thorsten Staudt,Frank Mücklich,Kinshuk Srivastava,Jessica Gola,Sebastian Scholl,Stefan Diebels,Dominik Britz

doi:10.1007/s00161-021-00980-x

Frederik Scherff, Thorsten Staudt + Show 6 more

Open Access

https://doi.org/10.1007/s00161-021-00980-x

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Abstract

Dual-phase steel shows a strong connection between its microstructure and its mechanical properties. This structure–property correlation is caused by the composition of the microstructure of a soft ferritic matrix with embedded hard martensite areas, leading to a simultaneous increase in strength and ductility. As a result, dual-phase steels are widely used especially for strength-relevant and energy-absorbing sheet metal structures. However, their use as heavy plate steel is also desirable. Therefore, a better understanding of the structure–property correlation is of great interest. Microstructure-based simulation is essential for a realistic simulation of the mechanical properties of dual-phase steel. This paper describes the entire process route of such a simulation, from the extraction of the microstructure by 3D tomography and the determination of the properties of the individual phases by nanoindentation, to the implementation of a simulation model and its validation by experiments. In addition to simulations based on real microstructures, simulations based on virtual microstructures are also of great importance. Thus, a model for the generation of virtual microstructures is presented, allowing for the same statistical properties as real microstructures. With the help of these structures and the aforementioned simulation model, it is then possible to predict the mechanical properties of a dual-phase steel, whose three-dimensional (3D) microstructure is not yet known with high accuracy. This will enable future investigations of new dual-phase steel microstructures within a virtual laboratory even before their production.

Highlights

Steel is the most important construction material of modern times, with a production quantity exceeding that of all other metals by more than a factor of 10 [1]
The set of material parameters determined for the individual phases is used for the microstructure-based simulation of the tensile test as material parameters for the two phases of the dual-phase steel
The quality of the adaptation of virtual structures to existing tomographies is determined with regard to the geometry parameters and the flow curves, to show that the model is able to create suitable virtual microstructures for the known real microstructures

Summary

Introduction

Steel is the most important construction material of modern times, with a production quantity exceeding that of all other metals by more than a factor of 10 [1]. Due to the large variety of possible microstructural states and alloy constituents, various classes of steels have been developed over time. One of these classes is dualphase steel. It consists of a soft ferritic matrix in which hard martensite regions are embedded.

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