Modeling the Mechanical Response of a Dual-Phase Steel Based on Individual-Phase Tensile Properties

In this work, the engineering stress–strain tensile curve and the force-deflection bending curve of two Dual-Phase (DP) steels are modeled, combining the mechanical data of fully ferritic and fully martensitic steels. The data is coupled by a modified law of mixture, which includes a partition param...

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Bibliographic Details
Main Authors: Paulina Alvarez, Francisco Muñoz, Diego Celentano, Alfredo Artigas, Felipe M. Castro Cerda, Jean-Philippe Ponthot, Alberto Monsalve
Format: Article
Language:English
Published: MDPI AG 2020-08-01
Series:Metals
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Online Access:https://www.mdpi.com/2075-4701/10/8/1031
Description
Summary:In this work, the engineering stress–strain tensile curve and the force-deflection bending curve of two Dual-Phase (DP) steels are modeled, combining the mechanical data of fully ferritic and fully martensitic steels. The data is coupled by a modified law of mixture, which includes a partition parameter <i>q</i> that takes into account the strength and strain distributions in both martensite and ferrite phases. The resulting constitutive model is solved in the context of the finite element method assuming a modified mixture rule in which a new parameter <i>q</i>′ is defined in order to extend the capabilities of the model to deal with triaxial stresses and strains and thus achieve a good agreement between experimental results and numerical predictions. The model results show that the martensite only deforms elastically, while the ferrite deforms both elastically and plastically. Furthermore, the partition factor <i>q</i>′ is found to strongly depend on the ferritic strain level. Finally, it is possible to conclude that the maximum strength of the studied DP steels is moderately influenced by the maximum strength of martensite.
ISSN:2075-4701