Damage Material Parameters Identification Using the ANN-GA Method and the Bulge Test

Hamdi Aguir; Hedi Bel Hadj Salah

doi:10.4028/www.scientific.net/KEM.554-557.928

Paper Titles

Microstructuring by a Combination of Micro Impact Extrusion and Shear Displacement Forming
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Accuracy of Transferring Microparts in a Multi Stage Former
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Sequential Optimization of Strip Bending Process Using Multiquadric Radial Basis Function Surrogate Models
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Surrogate POD Models for Parametrized Sheet Metal Forming Applications
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Damage Material Parameters Identification Using the ANN-GA Method and the Bulge Test
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On the Development and Computational Implementation of Complex Constitutive Models and Parameters’ Identification Procedures
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Development of an Inverse Routine to Predict Residual Stresses in the Material Based on a Bending Test
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A Two-Pronged Approach for the Assessment of Springback Variability for Sheet Metal Forming Applications
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Application of Tube Hydroforming in Square Cross-Section Die for Inverse Identification Method Validation
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HomeKey Engineering MaterialsKey Engineering Materials Vols. 554-557Damage Material Parameters Identification Using...

Damage Material Parameters Identification Using the ANN-GA Method and the Bulge Test

Abstract:

The simulation of the metal forming processes requires accurate constitutive models describing the material behaviour at finite strain, and taking into account several conditions. The choice of a rheological model and the determination of its parameters should be made from a test that generates such conditions. The major difficulty encountered is that there is no experimental test satisfying all these criteria. The use of more than one test seems well adapted, and is utilized to characterize the rheological behaviour at operating conditions corresponding to metal forming applications. Inverse analysis is then considered. Therefore, the difficulty lies with the long computing time that was taken when an optimization procedure is coupled with a finite element computation (FEC) to identify the material parameters. In order to solve the computing time problem, this paper proposes a hybrid identification method based on an artificial neural network and a genetic algorithm (ANN-GA). The proposed strategy is applied to identify the damage material parameters of the AISI 304 steel and using the bulge test.

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Periodical:

Key Engineering Materials (Volumes 554-557)

Pages:

928-935

DOI:

https://doi.org/10.4028/www.scientific.net/KEM.554-557.928

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Online since:

June 2013

Authors:

Hamdi Aguir, Hedi Bel Hadj Salah

Keywords:

Artificial Neural Network (ANN), Bulge Test, Damage Model, Genetic Algorithm (GA), Inverse Identification, Metal Forming

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