Your search keyword '"Dalila Vescovi"' showing total 2 results

1. A visco-elasto-plastic model for granular materials under simple shear conditions

Author

Dalila Vescovi, C. di Prisco, and Irene Redaelli

Subjects

Phase transition, State variable, Materials science, Constitutive equation, 0211 other engineering and technologies, Computational Mechanics, 02 engineering and technology, Mechanics, Geotechnical Engineering and Engineering Geology, Granular material, 01 natural sciences, Strength of materials, 010305 fluids & plasmas, Condensed Matter::Soft Condensed Matter, Simple shear, Void ratio, Classical mechanics, Shear (geology), Mechanics of Materials, 0103 physical sciences, General Materials Science, 021101 geological & geomatics engineering

Abstract

The numerical simulation of rapid landslides is quite complex mainly because constitutive models capable of simulating the mechanical behaviour of granular materials in the pre-collapse and post-collapse regimes are still missing. The goal of this paper is to introduce a constitutive model capable of capturing the response of dry granular flows from quasi-static to dynamic conditions, in particular when the material experiences a sort of solid-to-fluid phase transition. An ideal assembly of identical spheres under simple shear conditions is considered. In the constitutive model, void ratio and granular temperature have been chosen as state variables, and both shear and normal stresses are computed as the sum of two contributions: the quasi-static one and the collisional one. The former is determined by using a perfect elasto-plastic model including the critical state concept, while the latter is derived from the kinetic theory of granular gases. The evolution of the granular temperature, fundamentally governing the material phase transition, is obtained by imposing the kinetic fluctuating energy balance. The constitutive relationship has been integrated, under both constant pressure and constant volume conditions, and the influence of shear strain rate, initial void ratio and normal pressure on the mechanical response has been investigated.

Published

2015

2. From solid to granular gases: the steady state for granular materials

Author

Diego Berzi, Dalila Vescovi, and C. di Prisco

Subjects

State variable, Steady state, Materials science, Computational Mechanics, Inelastic collision, Thermodynamics, Strain rate, Geotechnical Engineering and Engineering Geology, Granular material, Shear rate, Simple shear, Shear strength (soil), Mechanics of Materials, General Materials Science

Abstract

SUMMARY This paper aims at extending the well-known critical state concept, associated with quasi-static conditions, by accounting for the role played by the strain rate when focusing on the steady, simple shear flow of a dry assembly of identical, inelastic, soft spheres. An additional state variable for the system, the granular temperature, is accounted for. The granular temperature is related to the particle velocity fluctuations and measures the agitation of the system. This state variable, as is in the context of kinetic theories of granular gases, is assumed to govern the response of the material at large strain rates and low concentrations. The stresses of the system are associated with enduring, frictional contacts among particles involved in force chains and nearly instantaneous collisions. When the first mechanism prevails, the material behaves like a solid, and constitutive models of soil mechanics hold, whereas when inelastic collisions dominate, the material flows like a granular gas, and kinetic theories apply. Considering a pressure-imposed flow, at large values of the normal stress and small values of the shear rate, the theory predicts a nonmonotonic shear rate dependence of the stress ratio at the steady state, which is likely to govern the evolution of landslides. Copyright © 2013 John Wiley & Sons, Ltd.

Published

2013