A multiscale modelling framework has been proposed to characterize microstructure evolution during hot strip rolling of transformation-induced plasticity (TRIP) steel. The modelling methodology encompasses a continuum dislocation density evolution model coupled with a lumped parameter heat transfer model which has been seamlessly integrated with a mesoscale Monte Carlo (MC) simulation technique. The dislocation density model computes the evolution of dislocation density and subsequently constitutive flow stress behaviour has been predicted and successfully validated with the published data. A lumped-parameter transient heat transfer model has been developed to calculate the average strip temperature in the time domain. The heat transfer mod...
In this work, the presence of dynamically formed ferrite above the Ae3 temperature during the physic...
Microalloyed steels offer a good combination of desirable mechanical properties by fine-tuning grain...
A novel simulation technique for predicting the microstructure and texture evolution during thermome...
A multiscale modelling procedure has been proposed to character evolution during hot strip rolling o...
A coupled Monte Carlo simulation technique has been developed for hot rolling of advanced high stren...
A Monte Carlo (MC) simulation methodology using high performance computing (HPC) has been proposed...
Models for the microstructure evolution during hot rolling are reviewed. The basic macroscopic pheno...
Recently, severe plastic deformation induced microstructure evolution has been studied through exten...
Recrystallization kinetics, during and after hot deformation, has been investigated for decades. Fro...
A computational modeling for predicting microstructure evolutions and mechanical properties of steel...
Severe temperature gradients and inhomogeneous strain distribution exist in the large cross-section ...
A mathematical model to predict the through-thickness temperature distribution in a steel strip duri...
The design of modern construction materials with heterogeneous microstructures requires a numerical ...
A viscoplastic constitutive model, coded as a User Material subroutine (UMAT) for use with the ABAQU...
The microstructure evolution of a martensitic Stainless steel subjected to hot compression is simula...
In this work, the presence of dynamically formed ferrite above the Ae3 temperature during the physic...
Microalloyed steels offer a good combination of desirable mechanical properties by fine-tuning grain...
A novel simulation technique for predicting the microstructure and texture evolution during thermome...
A multiscale modelling procedure has been proposed to character evolution during hot strip rolling o...
A coupled Monte Carlo simulation technique has been developed for hot rolling of advanced high stren...
A Monte Carlo (MC) simulation methodology using high performance computing (HPC) has been proposed...
Models for the microstructure evolution during hot rolling are reviewed. The basic macroscopic pheno...
Recently, severe plastic deformation induced microstructure evolution has been studied through exten...
Recrystallization kinetics, during and after hot deformation, has been investigated for decades. Fro...
A computational modeling for predicting microstructure evolutions and mechanical properties of steel...
Severe temperature gradients and inhomogeneous strain distribution exist in the large cross-section ...
A mathematical model to predict the through-thickness temperature distribution in a steel strip duri...
The design of modern construction materials with heterogeneous microstructures requires a numerical ...
A viscoplastic constitutive model, coded as a User Material subroutine (UMAT) for use with the ABAQU...
The microstructure evolution of a martensitic Stainless steel subjected to hot compression is simula...
In this work, the presence of dynamically formed ferrite above the Ae3 temperature during the physic...
Microalloyed steels offer a good combination of desirable mechanical properties by fine-tuning grain...
A novel simulation technique for predicting the microstructure and texture evolution during thermome...