Your search keyword '"M. Naaim"' showing total 2 results

1. Experimental and numerical study of granular flow and fence interaction

Author

M. Naaim, Thierry Faug, and Florence Naaim-Bouvet

Subjects

Fence (finance), Slope angle, 010506 paleontology, 010504 meteorology & atmospheric sciences, Flow (psychology), Surface finish, Mechanics, Snow, 01 natural sciences, Volume (thermodynamics), Range (statistics), Deposition (chemistry), Geology, 0105 earth and related environmental sciences, Earth-Surface Processes

Abstract

Dense snow avalanches are regarded as dry granular flows. This paper presents experimental and numerical modelling of deposition processes occurring when a gravity-driven granular flow meets a fence. A specific experimental device was set up, and a numerical model based on shallow-water theory and including a deposition model was used. Both tools were used to quantify how the retained volume upstream of the fence is influenced by the channel inclination and the obstacle height. We identified two regimes depending on the slope angle. In the slope-angle range where a steady flow is possible, the retained volume has two contributions: deposition along the channel due to the roughness of the bed and deposition due to the fence. The retained volume results only from the fence effects for higher slopes. The effects of slope on the retained volume also showed these two regimes. For low slopes, the retained volume decreases strongly with increasing slope. For higher slopes, the retained volume decreases weakly with increasing slope. Comparison between the experiments and computed data showed good agreement concerning the effect of fence height on the retained volume.

Published

2004

2. Dense and powder avalanches: momentumreduction generated by a dam

Author

Thierry Faug, Florence Naaim-Bouvet, and M. Naaim

Subjects

Entrainment (hydrodynamics), 010506 paleontology, Momentum (technical analysis), Jet (fluid), 010504 meteorology & atmospheric sciences, Physics::Instrumentation and Detectors, Flow (psychology), Mechanics, Snow, 01 natural sciences, Physics::Geophysics, Volume (thermodynamics), 13. Climate action, Deposition (phase transition), Air entrainment, Geology, 0105 earth and related environmental sciences, Earth-Surface Processes

Abstract

Passive protection structures reduce avalanche run-out distance and hence the potential damages brought about by an avalanche, by reducing its velocity and mass. This paper starts with a summary of the main existing results on interactions between snow avalanches and dams. In the case of dense avalanches, the effects of dams are re-examined and previous results are theoretically justified. For a powder-snow avalanche a dam has two primary effects. The momentum is reduced by the retarding force upstream of the dam and when the jet collides with the ground after the dam. Entrainment of air during the jet reduces its velocity since the mass increases. For a dense avalanche, there is a retarding force upstream of the dam and when the jet collides with the ground, but there is no significant effect of air entrainment. There is, however, deposition of snow which reduces the momentum of the avalanche without affecting the velocity. The reduction of the volume due to deposition reduces the spreading length and therefore the run-out distance of the avalanche. Downstream of the obstacle, the avalanche flow is regarded as an airborne jet. A comparative study shows that density and ambient-fluid entrainment effects are significant for gravity currents, powder and dense snow avalanches whereas they are negligible in granular flows.

Published

2004