Mechanical behaviour of multiphase materials : an intermediate mixture law without fitting parameter

“…The main effort has been dedicated to model the size effects in each phase in order to predict specific size effects on the macroscopic kinematical hardening. Calculations have been developed on the basis of existing microstructurebased approaches predicting the tensile curves [7,8] and rheological behavior at high strain of these ferrite-pearlite steels [9]. These models have directly inspired recent works of Hu et al [10] for instance.…”

Section: Introductionmentioning

confidence: 99%

Microstructure based modeling for the mechanical behavior of ferrite–pearlite steels suitable to capture isotropic and kinematic hardening

Allain

Bouaziz

2008

Materials Science and Engineering: A

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“…[80,81] Several forms of mixture laws were proposed for two-phase-system alloys. [76,[82][83][84][85][86][87][88] Bouquerel et al [62] have proposed a model for TRIP steels based on a mechanical law of mixture first proposed by Tamura et al [88] and the Mecking-Kocks theory. [89] The stress-strain curves of a CMnSi TRIP steel were predicted by combining the mechanical behavior of the isolated phases from the work of Samek et al [31,51] The isolated phases, i.e., ferrite and bainite, were prepared as bulk phases.…”

Section: Discussionmentioning

confidence: 99%

Static Strain Aging of Microstructural Constituents in Transformation-Induced-Plasticity Steel

Samek

Moor

Penning

et al. 2008

Metall Mater Trans A

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A pronounced difference in static strain aging was observed between unstrained and prestrained low-alloy multiphase transformation-induced-plasticity (TRIP) steel. High bake-hardening (BH) values were obtained for prestrained TRIP steel. This aging behavior was shown to be directly related to the multiphase microstructure, by analyzing static strain aging in the ferrite and bainite separately. The ferrite in TRIP steel exhibits very limited strain aging, due to the Cottrell atmosphere formation. The bainite constituent, which contains retained austenite, has a pronounced static strain-aging response in the 2 pct prestrained condition. This is a result of internal stresses generated by the strain-induced martensite and the low-temperature aging of this phase. In the absence of strain-induced martensite, the BH values of TRIP steel are low and are due only to the Cottrell atmosphere formation. The TRIP steel exhibits an intermediate BH response, due to the composite effect of its ferrite and bainite constituents. The influence of the cross-sectional changes and volume changes during tensile tests carried out to determine the BH values is also reviewed.

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Mechanical behaviour of multiphase materials : an intermediate mixture law without fitting parameter

Cited by 73 publications

References 1 publication

Microstructure based prediction of strain hardening behavior of dual phase steels

Microstructure based prediction of strain hardening behavior of dual phase steels

Microstructure based modeling for the mechanical behavior of ferrite–pearlite steels suitable to capture isotropic and kinematic hardening

Static Strain Aging of Microstructural Constituents in Transformation-Induced-Plasticity Steel

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