• Title of article

    DDSim: A hierarchical, probabilistic, multiscale damage and durability simulation system – Part I: Methodology and Level I

  • Author/Authors

    Emery، نويسنده , , J.M. and Hochhalter، نويسنده , , J.D. and Wawrzynek، نويسنده , , P.A. and Heber، نويسنده , , G. and Ingraffea، نويسنده , , A.R.، نويسنده ,

  • Issue Information
    روزنامه با شماره پیاپی سال 2009
  • Pages
    31
  • From page
    1500
  • To page
    1530
  • Abstract
    Current tools for fatigue life prediction of metallic structural components are limited in some or all of the following capabilities: geometry of, and boundary conditions on, the affected structural component, automation of the simulation process, randomness of the primary variables, and physics of the damage evolution processes. a next-generation damage and durability simulator, addresses each of these limitations with a hierarchical, multiscale, “search and simulate” strategy. This hierarchical strategy consists of three levels. Level I, described in this paper, performs an initial, reduced order, conservative screening, based on a linear finite element analysis of the uncracked component, to determine the most life-limiting locations for intrinsic material flaws. Initial flaw size can be specified deterministically, or generated randomly from statistical descriptions of the microstructure and used in Monte Carlo simulation. The result is a scalar field of predicted life over the entire domain of the structure. The benefits of the Level I analysis include a high degree of automation, solution speed, and easy implementation of high performance parallel computing resources. A validation case study of Level I is described. II and III are outlined herein, but will be described in further detail in subsequent papers. The Level II analysis uses FRANC3D to accurately predict the number of cycles consumed by microstructurally large crack growth processes. Level III performs multiscale analyses to accurately predict the cycles consumed in microstructurally small crack growth processes.
  • Keywords
    Multiscale , Probabilistic , Monte Carlo , Microstructural , damage tolerance , durability , Fatigue
  • Journal title
    ENGINEERING FRACTURE MECHANICS
  • Serial Year
    2009
  • Journal title
    ENGINEERING FRACTURE MECHANICS
  • Record number

    2342845