Modeling Recrystallization for 3D Multi-Pass Forming Processes

Mihaela Teodorescu; Patrice Lasne; Roland E. Logé

doi:10.4028/www.scientific.net/MSF.558-559.1201

Paper Titles

Simulation of Ideal Grain Growth Using the Multi-Phase-Field Model
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Topology Based Growth Law and New Analytical Grain Size Distribution Function of 3D Grain Growth
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Phase-Field Modeling of Recrystallization - Effects of Second-Phase Particles on the Recrystallization Kinetics
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Phase-Field Modeling and Simulation of Nucleation and Growth of Recrystallized Grains
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Modeling Recrystallization for 3D Multi-Pass Forming Processes
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Stored Energy and Recrystallisation in Cold Rolled Steel
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Coupled Simulation of the Static Recrystallization in Hot Deformed Austenite on Mesoscale
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Monte Carlo Potts Model Simulation and Statistical Theory of 3D Grain Growth
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Diffusion Controlled Abnormal Grain Growth in Ceramics
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HomeMaterials Science ForumMaterials Science Forum Vols. 558-559Modeling Recrystallization for 3D Multi-Pass...

Modeling Recrystallization for 3D Multi-Pass Forming Processes

Abstract:

The present work concerns the simulation of metallurgical evolutions in 3D multi-pass forming processes. In this context, the analyzed problem is twofold. One point refers to the management of the microstructure evolution during each pass or each inter-pass period and the other point concerns the management of the multi-pass aspects (different grain categories, data structure). In this framework, a model is developed and deals with both aspects. The model considers the microstructure as a composite made of a given (discretized) number of phases which have their own specific properties. The grain size distribution and the recrystallized volume fraction distribution of the different phases evolve continuously during a pass or inter-pass period. With this approach it is possible to deal with the heterogeneity of the microstructure and its evolution in multi-pass conditions. Both dynamic and static recrystallization phenomena are taken into account, with typical Avrami-type equations. The present model is implemented in the Finite Element code FORGE2005®. 3D numerical simulation results for a multi-pass process are presented.

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Materials Science Forum (Volumes 558-559)

Pages:

1201-1206

DOI:

https://doi.org/10.4028/www.scientific.net/MSF.558-559.1201

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Online since:

October 2007

Authors:

Mihaela Teodorescu, Patrice Lasne, Roland E. Logé

Keywords:

Dynamic Recrystallization (DRX), Finite Element, Forming, Metadynamic Recrystallisation, Multi-Pass, Static Recrystallization

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