Granular Avalanches in Fluids

Abstract: Three regimes of granular avalanches in fluids are put in light depending on the Stokes number St which prescribes the relative importance of grain inertia and fluid viscous effects, and on the grain/fluid density ratio r. In gas (r ≫ 1 and St > 1, e.g., the dry case), the amplitude and time duration of avalanches do not depend on any fluid effect. In liquids (r ∼ 1), for decreasing St, the amplitude decreases and the time duration increases, exploring an inertial regime and a viscous regime. These regimes are… Show more

“…In both cases, the maximal velocity at the surface agrees with the characteristic velocity of the regime [14]:…”

“…[10,11,13,[28][29][30]. To compare and discuss more in details those velocity profiles, we will first refer to the work carried out by Courrech du Pont et al [14] who have defined three flow regimes for a granular avalanche in a fluid based on the fall under gravity of one grain in fluid: a free fall regime for which there is no fluid influence (i.e. the classical dry regime) and two regimes where the avalanche dynamics is controlled by the fluid drag force and for which the grain motion reaches respectively a viscous and an inertial limit regime.…”

“…Following their definitions of the relevant dimensionless groups, namely Stokes number and grain/fluid density ratio, our experiments appear to be situated in the close vicinity of the boundary between viscous and inertial limit regime with a particle Reynolds number Re 2 ≈ . But, for such values of Re close to unity in this case, we can no more use the Stokes drag force (valid only for Re 1 ≪ ) in the whole viscous regime or a constant drag coefficient (valid only for Re 1 ≫ ) in the whole inertial regime as was done in [14]. To clarify this point, we propose to connect the two limit regimes with the following empirical expression of the drag coefficient derived from [31]: With an analysis analogous to [14], the rheology obtained for dry granular flows [13] has been extended to steady granular flows down an inclined plane taking into account the influence of the interstitial fluid [15].…”

“…But, for such values of Re close to unity in this case, we can no more use the Stokes drag force (valid only for Re 1 ≪ ) in the whole viscous regime or a constant drag coefficient (valid only for Re 1 ≫ ) in the whole inertial regime as was done in [14]. To clarify this point, we propose to connect the two limit regimes with the following empirical expression of the drag coefficient derived from [31]: With an analysis analogous to [14], the rheology obtained for dry granular flows [13] has been extended to steady granular flows down an inclined plane taking into account the influence of the interstitial fluid [15]. Specific rheological laws are achieved for the three regimes which predict in particular that the velocity profiles in both free fall and inertial limit regimes are qualitatively similar.…”

“…According to the definition of three regimes of avalanches in fluids [14], the local rheology has been subsequently extended to the case of submarine granular flows down inclined planes [15].…”

Sensitivity to solid volume fraction of gravitational instability in a granular medium

“…In both cases, the maximal velocity at the surface agrees with the characteristic velocity of the regime [14]:…”

“…[10,11,13,[28][29][30]. To compare and discuss more in details those velocity profiles, we will first refer to the work carried out by Courrech du Pont et al [14] who have defined three flow regimes for a granular avalanche in a fluid based on the fall under gravity of one grain in fluid: a free fall regime for which there is no fluid influence (i.e. the classical dry regime) and two regimes where the avalanche dynamics is controlled by the fluid drag force and for which the grain motion reaches respectively a viscous and an inertial limit regime.…”

“…Following their definitions of the relevant dimensionless groups, namely Stokes number and grain/fluid density ratio, our experiments appear to be situated in the close vicinity of the boundary between viscous and inertial limit regime with a particle Reynolds number Re 2 ≈ . But, for such values of Re close to unity in this case, we can no more use the Stokes drag force (valid only for Re 1 ≪ ) in the whole viscous regime or a constant drag coefficient (valid only for Re 1 ≫ ) in the whole inertial regime as was done in [14]. To clarify this point, we propose to connect the two limit regimes with the following empirical expression of the drag coefficient derived from [31]: With an analysis analogous to [14], the rheology obtained for dry granular flows [13] has been extended to steady granular flows down an inclined plane taking into account the influence of the interstitial fluid [15].…”

“…But, for such values of Re close to unity in this case, we can no more use the Stokes drag force (valid only for Re 1 ≪ ) in the whole viscous regime or a constant drag coefficient (valid only for Re 1 ≫ ) in the whole inertial regime as was done in [14]. To clarify this point, we propose to connect the two limit regimes with the following empirical expression of the drag coefficient derived from [31]: With an analysis analogous to [14], the rheology obtained for dry granular flows [13] has been extended to steady granular flows down an inclined plane taking into account the influence of the interstitial fluid [15]. Specific rheological laws are achieved for the three regimes which predict in particular that the velocity profiles in both free fall and inertial limit regimes are qualitatively similar.…”

“…According to the definition of three regimes of avalanches in fluids [14], the local rheology has been subsequently extended to the case of submarine granular flows down inclined planes [15].…”

Sensitivity to solid volume fraction of gravitational instability in a granular medium

References

Experiments on floating bed rotating drums using magnetic particle tracking