Crystal plasticity simulations help to understand the local deformation behavior of multi-phase materials based on the microstructural attributes. The results of such simulations are mainly dependent on the Representative Volume Element (RVE) size and composition. The effect of RVE thickness on the changing global and local stress and strain is analyzed in this work for a test case of dual-phase steels in order to identify the minimal RVE thickness for obtaining consistent results. 100×100×100 voxel representative volume elements are constructed by varying grain size and random orientation distribution in DREAM-3D. The constructed RVEs are sliced in depth up to 1, 5, 10, 15, 20, 25, 30, 40, and 50 layers to construct different geometries with increasing thickness. Crystal plasticity model parameters for ferrite and martensite are taken from already published data and assigned to respective phases. Although the global stress/strain behavior of different RVEs is similar (<5 % divergence), the local stress/strain partitioning in RVEs with varying thickness and grain size shows a considerable variation when statistically compared. It is concluded that two-dimensional (2D) RVEs can be used for crystal plasticity simulations when global deformation behavior is of interest. Whereas, it is necessary to consider three-dimensional (3D) RVEs, which have a specific thickness and number of grains for determining stabilized and more accurate local deformation behavior. This estimation will help researchers in optimizing the computation time for accurate mesoscale simulations.
In the first part, a brief introduction to a general non‐isothermal layer model for symmetric but inhomogeneous rolling conditions is presented. The model is based on an extended slab theory. Additional to conventional approaches, a phenomenological layer thickness model for NS‐layers and its application to several rolling conditions is briefly described in part I. Within the course of computation for the stress and strain state internal stresses at the entrance and exit of the roll gap are predicted as a closing condition for the derived set of kinematic and kinetic equations. They transform elastically outside the roll gap to residual stresses. In this part, first comparisons are given to finite element solutions and experimental investigations. The results of an extensive case study will be given in part II. Due to the used coupling between kinematics and kinetics, a significant improvement of the slab theory in relation to a local description of an inhomogeneous plane strain deformation and stress state is found.
In this study, DAMASK was used to model and elucidate the microstructural deformation behavior of sintered X3CrMnNi16-7-6 TRIP steel. The recently developed TRIP-TWIP material model was used within the DAMASK framework. Material optimization was performed using the least computationally expensive method, which yielded the desired results. The physical parameters of the material model were identified and tuned to fit the experimental observations. This tuned material model was used to run simulations utilizing 2D EBSD data. The local deformation, transformation, and twinning behaviors of the material under quasi-static tensile and compressive loads were analyzed. The results of this are in good agreement with previous experimental observations. The phenomena of dislocation glide, twinning, martensitic transformation, stress evolution, and dislocation pinning in different deformation stages are discussed.
In this research, the effect of 2D and 3D Representative Volume Element (RVE) on the ductile damage behavior in single-phase (only ferrite) and dual-phase (ferrite and martensite) steels is analyzed. Physical and fitting parameters of the constitutive model for bcc-ferrite and bcc-martensite phases are adapted from the already published work. Crystal plasticity (CP) based numerical simulations without damage consideration are run and, later, ductile damage criteria for the ferrite phase is defined for all cases. The results of the non-damage (-nD-) and damage (-D-) simulations are compared to analyze the global and local differences of evolving stresses and strains. It is observed that for the same model parameters defined in all cases, damage initiation occurs at the overall higher global strain in the case of 3D compared to 2D. Based on statistical data analysis, a systematic comparison of local results is carried out to conclude that the 3D RVEs provide better quantitative and qualitative results and should be considered for such full phase simulations. Whereas 2D RVEs are simple to analyze and provide appropriate qualitative information about the damage initiation sites.
A Transformation-Induced Plasticity (TRIP) steel matrix reinforced with magnesium-partially stabilized zirconia (Mg-PSZ) particles depicts a superior energy absorbing capacity during deformation. In this research, the TRIP/TWIP material model already developed in the framework of the Düsseldorf Advanced Material Simulation Kit (DAMASK) is tuned for X8CrMnNi16-6-6 TRIP steel and 10% Mg-PSZ composite. A new method is explained to more accurately tune this material model by comparing the stress/strain, transformation, twinning, and dislocation glide obtained from simulations with respective experimental acoustic emission measurements. The optimized model with slight modification is assigned to the steel matrix in 10% Mg-PSZ composite material. In the simulation model, zirconia particles are assigned elastic properties with a perfect ceramic/matrix interface. Local deformation, transformation, and the twinning behavior of the steel matrix due to quasi-static tensile load were analyzed. The comparison of the simulation results with acoustic emission data shows good correlation and helps correlate acoustic events with physical attributes. The tuned material models are used to run full phase simulations using 2D Electron Backscatter Diffraction (EBSD) data from steel and 10% Mg-PSZ zirconia composites. Form these simulations, dislocation glide, martensitic transformation, stress evolution, and dislocation pinning in different stages of deformation are qualitatively discussed for the steel matrix and ceramic inclusions.
Within the FOR3010 Refrabund project, a new type of composite refractory consisting of alumina and refractory metals such as tantalum and niobium is developed. This material is characterized by its ability to conduct electricity, which offers new opportunities for functional parts in high‐temperature environments. To support the development of material properties and production technology, a new simulation approach is needed, which is able to describe irregularly shaped particles of at least two different phases. Current simulations of sintering processes work often with heavily idealized powder geometries. As sintering is mainly driven by gradients of chemical potential due to surface curvatures, a realistic description of the particle geometry is essential for achieving precise simulation results. Herein, a new approach of modeling the sintering behavior of irregularly shaped powder particles by the use of a finite differences approach is developed. A discrete description of irregular powder particles is introduced, and the diffusional flows at their surfaces and sintering necks as well as their development in time are calculated. The new model is compared with an older model using spherical particle geometries from literature. Comparison with experimental results follows in a subsequent publication.
For development of new materials and improvement of material properties today simulation of the production processes is essential. The understanding of the processes' mechanics and thermodynamics give the ability of tuning the process toward property improvement and efficiency. Flat rolling is one of the main processes used for production of flat metal semiproducts such as sheets, strips, and plates. In simulation of flat rolling today, two main approaches are used. The first is the elementary theory of plasticity, also known as strip or slab method, which was the first theoretical approach to describe the conditions within the roll gap. The second one is the finite element method, which offers a general approach for complex problems.The elementary theory was established by von Kármán. [1] Well-known contributors are Ford et al., [2][3][4] Orowan, [5] and Alexander. [6] In recent years, only few new contributions to this topic were published, for example, Kim et al., [7] Schmidtchen and Kawalla, [8] and Freshwater. [9,10] This approach's main benefit is the fast computation speed due to 1D differential equation formulation.The finite element theory is actively developed since the 1980s, for example, by Hwu and Lenard, [11] Jamal et al., [12] Jiang and Tieu, [13] Rout et al., [14] and Kainz et al. [15] . It provides a general approach for complex problems in two or three dimensions and offers the high accuracy of the simulation results. The main disadvantage is the high computational effort in solving the equation systems, increasing rapidly with nonlinearity of the base equations and resolution of the problem space. Therefore, this method has grown along with the development of high-performance computer systems in the past decades. However, fast methods are needed for use in control systems or production scheduling. Some authors try to combine the slab method with partial finite element solutions to achieve a decrease in computation time, for example, Kim et al. [7] . Another approach was shown by Schmidtchen and Kawalla [8] in extending the elementary theory by dividing the strip element into a number of discrete layers. This turns the 1D resolution of the elementary theory into a 2D one. Nevertheless, this model only requires 1D differential equation solving, which can be done fast and easy with common numerical methods. Due to this 1D formulation, it can be easily coupled with microstructure and precipitation models. The model is currently used in industry for online-simulation and controlling of direct input steel plants, including microstructure and precipitation simulation. Due to the layering, it is suitable for inhomogeneity determined processes, such as block rolling and direct input, were conventional slab method fails. However, it is only able to describe the layers as in plastic or rigid state. This work has the aim to extend it by elastic-plastic material behavior. The influence of the elastic behavior should be investigated in comparison with the rigid-plastic layer model as well as to FEM simulatio...
A fast simulation of the inhomogeneous materials evolution during the deformation steps and its effect on subsequent processes is demanded for the development of new technologies for materials with a homogeneous microstructure. In the paper a layer model for flat hot and cold rolling is presented. A deepened understanding of the influence of inhomogeneities in material state and material flow on the whole process can be reached due to the introduction of a new computational concept for variable layer thickness distributions in the layer model. The concept will be explained and the additional information obtained concerning the influence of shear, local residual stresses as well as inhomogeneous stress and strain states in the roll gap on the microstructure evolution will be presented and discussed.
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