• Title of article

    On the rheology of dilative granular media: Bridging solid- and fluid-like behavior

  • Author/Authors

    Andrade، نويسنده , , José E. and Chen، نويسنده , , Qiushi and Le، نويسنده , , Phong H. and Avila، نويسنده , , Carlos F. and Matthew Evans، نويسنده , , T.، نويسنده ,

  • Issue Information
    روزنامه با شماره پیاپی سال 2012
  • Pages
    15
  • From page
    1122
  • To page
    1136
  • Abstract
    A new rate-dependent plasticity model for dilative granular media is presented, aiming to bridge the seemingly disparate solid- and fluid-like behavioral regimes. Up to date, solid-like behavior is typically tackled with rate-independent plasticity models emanating from Mohr–Coulomb and Critical State plasticity theory. On the other hand, the fluid-like behavior of granular media is typically treated using constitutive theories amenable to viscous flow, e.g., Bingham fluid. In our proposed model, the material strength is composed of a dilation part and a rate-dependent residual strength. The dilatancy strength plays a key role during solid-like behavior but vanishes in the fluid-like regime. The residual strength, which in a classical plasticity model is considered constant and rate-independent, is postulated to evolve with strain rate. The main appeal of the model is its simplicity and its ability to reconcile the classic plasticity and rheology camps. The applicability and capability of the model are demonstrated by numerical simulation of granular flow problems, as well as a classical shear banding problem, where the performance of the continuum model is compared to discrete particle simulations and physical experiment. These results shed much-needed light onto the mechanics and physics of granular media at various shear rates.
  • Keywords
    dilatancy , Granular media , rheology , rate-dependent , plasticity
  • Journal title
    Journal of the Mechanics and Physics of Solids
  • Serial Year
    2012
  • Journal title
    Journal of the Mechanics and Physics of Solids
  • Record number

    1428050