Identification Problem of Internal Variables Model of Material

Danuta Szeliga; Roman Kuziak; Maciej Pietrzyk

doi:10.4028/www.scientific.net/KEM.651-653.1339

Paper Titles

Recent Developments in LS-DYNA to close the Virtual Process Chain for Forming, Press Hardening and Welding
p.1312

Agile Multiscale Modelling of the Thermo-Mechanical Processing of an Aluminium Alloy
p.1319

Virtual Joining Factory – Integration of Microstructure Evolution in the Manufacturing Process Chain Simulation
p.1325

Simulation of Incremental Forming Processes Using a Thermo-Mechanical Partitioned Algorithm
p.1331

Identification Problem of Internal Variables Model of Material
p.1339

Inverse Analysis Procedure to Determine Flow Stress and Friction Data for Metal Cutting Finite Element Modeling
p.1345

Using Data Sampling and Inverse Optimization for the Reduction of the Experimental Effort in the Characterization of Hot Working Behaviour for a Case Hardening Steel
p.1351

Determination of Thermal Boundary Conditions for Modeling the Hot Roll Bonding Process
p.1357

Inverse Identification of Process Variations for Thin Steel Sheet Bending
p.1363

HomeKey Engineering MaterialsKey Engineering Materials Vols. 651-653Identification Problem of Internal Variables Model...

Identification Problem of Internal Variables Model of Material

Abstract:

The paper deals with the identification of material model based on the internal variable. The model with one internal variable, which was average dislocation density, was considered. Identification was performed using inverse analysis (IA) of uniaxial compression tests. In this work IA was transformed to an optimization task and the goal function was defined as difference (in Euclid's norm) between measured and calculated parameters: loads in plastometric tests (used to identify flow stress) and stresses in stress relaxation tests (used to identify recrystallization kinetics). Exploring a possibility of making the identification more reliable by application the Sensitivity Analysis (SA) was the main objective of the work. The IA was preceded by SA of the model output with respect to the model parameters to select an efficient optimization algorithm and/or eliminate local minima. Selected results of identification for different materials are presented in the paper, as well.

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Periodical:

Key Engineering Materials (Volumes 651-653)

Pages:

1339-1344

DOI:

https://doi.org/10.4028/www.scientific.net/KEM.651-653.1339

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Online since:

July 2015

Authors:

Danuta Szeliga*, Roman Kuziak, Maciej Pietrzyk

Keywords:

Identification, Internal Variable, Inverse Analysis, Material Model, Sensitivity Analysis

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