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A Sequential FEM-SPH Model of the Heating-Remelting-Cooling of Steel Samples in the Gleeble 3800 Thermo-Mechanical Simulator System

Marcin Hojny
Archives of Foundry Engineering | 2020 | vol. 20 | No 3 | 60-68 | DOI: 10.24425/afe.2020.133331
Keywords Smoothed particle hydrodynamics Finite element method Solidification Physical simulation Computer simulation
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Abstract

This article presents a sequential model of the heating-remelting-cooling of steel samples based on the finite element method (FEM) and the smoothed particle hydrodynamics (SPH). The numerical implementation of the developed solution was completed as part of the original DEFFEM 3D package, being developed for over ten years, and is a dedicated tool to aid physical simulations performed with modern Gleeble thermo-mechanical simulators. Using the developed DEFFEM 3D software to aid physical simulations allows the number of costly tests to be minimized, and additional process information to be obtained, e.g. achieved local cooling rates at any point in the sample tested volume, or characteristics of temperature changes. The study was complemented by examples of simulation and experimental test results, indicating that the adopted model assumptions were correct. The developed solution is the basis for the development of DEFFEM 3D software aimed at developing a comprehensive numerical model allows the simulation of deformation of steel in semi solid state.

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Authors and Affiliations

Marcin Hojny

Simulation of Hot Continuous Rolling of a Plain Carbon Steel Using the MAXStrain II® Multi-Axis Deformation System

I. Schindler P. Kawulok K. Konečná M. Sauer H. Navrátil P. Opěla R. Kawulok S. Rusz
Archives of Metallurgy and Materials | 2023 | vol. 68 | No 2 | 741-747 | DOI: 10.24425/amm.2023.142456
Keywords MAXStrain II system multi-axis deformations hot continuous rolling physical simulation
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Abstract

A simple methodology was used for calculating the equivalent strain values during forming the sample alternately in two mutually perpendicular directions. This method reflects an unexpected material flow out of the nominal deformation zone when forming on the MAXStrain II device. Thus it was possible to perform two temperature variants of the simulation of continuous rolling and cooling of a long product made of steel containing 0.17% C and 0.80% Mn. Increasing the finishing temperature from 900°C to 950°C and decreasing the cooling rate from 10°C/s to 5°C/s led to a decrease in the content of acicular ferrite and bainite and an increase in the mean grain size of proeutectoid ferrite from about 8 µm to 14 µm. The result was a change in the hardness of the material by 15%.
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Authors and Affiliations

I. Schindler
1
ORCID: ORCID
P. Kawulok
1
ORCID: ORCID
K. Konečná
1
ORCID: ORCID
M. Sauer
1
ORCID: ORCID
H. Navrátil
1
ORCID: ORCID
P. Opěla
1
ORCID: ORCID
R. Kawulok
1
ORCID: ORCID
S. Rusz
1
ORCID: ORCID
  1. VŠB – Technical University of Ostrava, Faculty of Materials Science and Technology, Ostrava, Czech Republic

Spatial Thermo-Mechanical Model of Mushy Steel Deformation Based on the Finite Element Method

Marcin Hojny Tomasz Dębiński M. Głowacki Trang Thi Thu Nguyen
Archives of Foundry Engineering | 2021 | vo. 21 | No 2 | 17-28 | DOI: 10.24425/afe.2021.136093
Keywords Mechanical properties Soft-reduction Semi-solid Numerical modelling Physical simulation
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Abstract

The paper reports the results of work leading to the construction of a spatial thermo-mechanical model based on the finite element method allowing the computer simulation of physical phenomena accompanying the steel sample testing at temperatures that are characteristic for the soft-reduction process. The proposed numerical model is based upon a rigid-plastic solution for the prediction of stress and strain fields, and the Fourier-Kirchhoff equation for the prediction of temperature fields. The mushy zone that forms within the sample volume is characterized by a variable density during solidification with simultaneous deformation. In this case, the incompressibilitycondition applied in the classic rigid-plastic solution becomes inadequate. Therefore, in the presented solution, a modified operator equation in the optimized power functional was applied, which takes into account local density changes at the mechanical model level (the incompressibility condition was replaced with the condition of mass conservation). The study was supplemented withexamples of numerical and experimental simulation results, indicating that the proposed model conditions, assumptions, and numerical models are correct.
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Bibliography

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Authors and Affiliations

Marcin Hojny
Tomasz Dębiński
ORCID: ORCID
M. Głowacki
1
Trang Thi Thu Nguyen
1
  1. AGH University of Science and Technology, Cracow, Poland

Multiscale model of heating-remelting-cooling in the Gleeble 3800 thermo-mechanical simulator system

M. Hojny M. Głowacki P. Bała W. Bednarczyk W. Zalecki
Archives of Metallurgy and Materials | 2019 | vol. 64 | No 1 | 401-412 | DOI: 10.24425/amm.2019.126266
Keywords DEFFEM package finite element method Monte Carlo method physical simulation computer simulation mushyzone extra-high temperatures
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Abstract

The paper presents a multi-scale mathematical model dedicated to a comprehensive simulation of resistance heating combined with the melting and controlled cooling of steel samples. Experiments in order to verify the formulated numerical model were performed using a Gleeble 3800 thermo-mechanical simulator. The model for the macro scale was based upon the solution of Fourier-Kirchhoff equation as regards predicting the distribution of temperature fields within the volume of the sample. The macro scale solution is complemented by a functional model generating voluminal heat sources, resulting from the electric current flowing through the sample. The model for the micro-scale, concerning the grain growth simulation, is based upon the probabilistic Monte Carlo algorithm, and on the minimization of the system energy. The model takes into account the forming mushy zone, where grains degrade at the melting stage – it is a unique feature of the micro-solution. The solution domains are coupled by the interpolation of node temperatures of the finite element mesh (the macro model) onto the Monte Carlo cells (micro model). The paper is complemented with examples of resistance heating results and macro- and micro-structural tests, along with test computations concerning the estimation of the range of zones with diverse dynamics of grain growth.

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Authors and Affiliations

M. Hojny
M. Głowacki
P. Bała
W. Bednarczyk
W. Zalecki

Physical Simulation of Individual Heat-Affected Zones in S960MC Steel

M. Mičian J. Winczek D. Harmaniak R. Koňár M. Gucwa J. Moravec
Archives of Metallurgy and Materials | 2021 | vol. 66 | No 1 | 81-89 | DOI: 10.24425/amm.2021.134762
Keywords mechanical properties of heat affected zone steel S960MC physical simulation Gleeble 3500
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Abstract

This research is focused on the analysis of heat-affected sub-zones in 2 mm thick steel S960MC samples, with the aim of observing and evaluating the mechanical properties after exposure to temperatures corresponding to individual heat-affected sub-zones. Test samples were prepared using a Gleeble 3500 thermo-mechanical simulator. The samples were heated in the range from 550°C to 1350°C and were subsequently quickly cooled. The specimens, together with the base material, were then subjected to tensile testing, impact testing, and micro-hardness measurements in the sample cross-section, as well as evaluation of their microstructure. Fracture surfaces are investigated in samples after impact testing. The heat-affected sub-zones studied indicate high sensitivity to the thermal input of welding. There is a significant decrease in tensile strength and yield strength at temperatures around 550°C.

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Authors and Affiliations

M. Mičian
ORCID: ORCID
J. Winczek
D. Harmaniak
R. Koňár
M. Gucwa
J. Moravec

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