Abstract
Most granular materials encountered in nature and industry lie either in the quasi-static regime or the intermediate dense flow regime. Debris materials are a typical granular material with viscous interstitial fluid and show solid-like behaviors before failure and fluid-like behaviors after failure. Based on Bagnold’s pioneering work on granular–fluid flows, we propose a framework for constitutive model development, which has an additive form. Based on this framework, a unified constitutive model for granular–fluid material in the quasi-static and dense flow regimes is developed. The main intergranular interactions and granular–fluid interactions controlling the mechanical behaviors are taken into account using the Mohr–Coulomb model and a Bagnold-type relation. Dry granular flows in three simple configurations, i.e., plain shear, vertical chute flow and flow on an inclined plane, are studied. Analytical solutions based on the presented unified model are obtained. Comparisons between results from the presented model and the $$\mu (I)$$ model indicate that the explicit partition of frictional and collisional stress components provides insights into dense granular flows. In addition, the new model is used to predict the stress–strain relations in two annular shear tests. The applicability and advantages of the unified model are discussed.
Highlights
Granular flows are widely presented in industry and nature, e.g., raw material processing and geophysical flows
Debris flows are typical granular flows with viscous interstitial fluid which show solid-like behaviors before failure and fluid-like behaviors after failure
This paper aims to develop a framework of constitutive modeling to unify the constitutive theories for the solid-like and fluid-like behaviors of a granular-fluid mixture
Summary
Granular flows are widely presented in industry and nature, e.g., raw material processing and geophysical flows. The viscosity of the interstitial fluid and the particle collisions are believed to be dominant factor in the macro-viscous regime and grain-inertia regime, respectively. Frictional contact and collision are not explicitly considered in this model As it is developed for dry granular flow, the drag force imposed on the solid particles by the viscous interstitial fluid is not taken into account. A simple shearing model is developed based on the framework by employing the Bagnoldtype relations for the dense flow regimes and the elastoplastic theory, a Mohr-Coulombtype relation, for the quasi-static regime. Based on the effort devoted to examine Bagnold’s pioneer work [9, 10, 11, 12], the constitutive relations for the macroviscous and grain-inertia regimes are modified and unified in the new model to consider the dynamic behaviors. The applicability and advantages of the unified model are discussed
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