• Title of article

    Microstructure-based multiscale modeling of elevated temperature deformation in aluminum alloys Original Research Article

  • Author/Authors

    Paul E. Krajewski، نويسنده , , Louis G. Hector Jr ، نويسنده , , Ningning Du، نويسنده , , Allan F. Bower ، نويسنده ,

  • Issue Information
    دوهفته نامه با شماره پیاپی سال 2010
  • Pages
    13
  • From page
    1074
  • To page
    1086
  • Abstract
    A multiscale model for predicting elevated temperature deformation in Al–Mg alloys is presented. Constitutive models are generated from a theoretical methodology and used to investigate the effects of grain size on formability. Flow data are computed with a polycrystalline, microstructure-based model which accounts for grain boundary sliding, stress-induced diffusion, and dislocation creep. Favorable agreement is found between the computed flow data and elevated temperature tensile measurements. A creep constitutive model is then fit to the computed flow data and used in finite-element simulations of two simple gas pressure forming processes, where favorable results are observed. These results are fully consistent with gas pressure forming experiments, and suggest a greater role for constitutive models, derived largely from theoretical methodologies, in the design of Al alloys with enhanced elevated temperature formability. The methodology detailed herein provides a framework for incorporation of results from atomistic-scale models of dislocation creep and diffusion.
  • Keywords
    Aluminum alloys , Creep , Grain boundaries , Micromechanical modeling , Superplasticity
  • Journal title
    ACTA Materialia
  • Serial Year
    2010
  • Journal title
    ACTA Materialia
  • Record number

    1144716