A microstructure-based constitutive model for pearlite.

Fully pearlitic eutectoid steels have an excellent compromise of mechanical strength and ductility and are widely used for rails, prestressing tendons and high- strength wires. These excellent mechanical properties are a consequence of their particular nanocomposite structure combining thin cementit...

Descripción completa

Detalles Bibliográficos
Autor: Rodríguez-Páez, J.A. (Jorge Adrián)|||/items/1ecd081f-440c-4b57-8343-dd827eae8f69
Tipo de recurso: tesis doctoral
Fecha de publicación:2023
País:España
Institución:Universidad de Navarra
Repositorio:Dadun. Depósito Académico Digital de la Universidad de Navarra
Idioma:inglés
OAI Identifier:oai:dadun.unav.edu:10171/69092
Acceso en línea:https://hdl.handle.net/10171/69092
Access Level:acceso abierto
Palabra clave:Constitutive model.
Pearlitic steels.
Internal stresses.
Plasticity.
Anisotropy.
Continuum damage mechanics.
Descripción
Sumario:Fully pearlitic eutectoid steels have an excellent compromise of mechanical strength and ductility and are widely used for rails, prestressing tendons and high- strength wires. These excellent mechanical properties are a consequence of their particular nanocomposite structure combining thin cementite lamellae (~12% volume fraction) with ferritic lamellae. This complex substructure entails a complex microstructural and property evolution with applied strain that is difficult to model. In this work, a microstructure-based constitutive model for pearlite accounting for both the elastoplastic behaviour and the damage evolution is presented. The original formulation, valid for mesoscopic scales, considers the behaviour of ferrite and cementite separately, assuming that strengthening occurs through the mechanisms acting in ferrite. For its application in macro-scale systems such as wire drawing, a multi-colony homogenization strategy has been applied. For damage, a Continuum Damage Mechanics approach adapted to the features of pearlite has been adopted with the coupling of damage to the mechanical response. The model has been implemented for use in finite element simulations and has been calibrated using experimental data of tensile and torsion tests. Subsequently, the model has been validated, confirming its predictive capabilities across various aspects, including the mechanical response under different stress states, the build-up of internal stresses and the evolution of the microstructure with deformation.