The dense avalanches of dry are regarded as dry granular flows. A numerical model based on the shallow water theory was developed. Friction is represented by a phenomenological law issued from the recent progress in the granular mediums and snow avalanches research. By means of assumptions similar to those employed in the shallow water theory, a formulation of erosion and deposition mass fluxes was highlighted. The obtained system of equations was solved thanks to a finite volumes numerical scheme. The model was afterwards severely tested on analytical solutions and experimental data. We afterwards studied the deposits produced by a dam. A specific experimental device was installed. Experimental and numerical data, were used to study how the volume retained upstream of the barrier is influenced by the slope of the channel and the size of the obstacle. The comparison between the experiments and the simulated data showed a good agreement concerning both the effect of the size of the barrier and the slope of the terrain on the retained volume. We substituted in the numerical model, the granular friction law by a snow friction one determined empirically by Cassassa (1991) and confirmed by the experiments we undertaken at Col du Lac Blanc. We afterwards exploited the existing avalanches data (153 events) of a real path. We calibrated the friction coefficient on each avalanche and analysed its statistical distribution in the case of the depth average model and in the case of centre of mass model. Afterwards, we studied the effect of a dam of different heights placed at two different positions in the path. We analysed their effectiveness as well in terms of run-out distance shortening as in terms of retained volume. It comes out from this analysis the prevailing role of the friction coefficient on the dynamics of the avalanche and on the effectiveness of the dike.