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Massive Particles

Relatively larger particles are used in some systems like fluidized beds, where the inertial effect is not negligible anymore. For such massive particles, a dynamics presented in Ref. [16,17] is implemented:
$\displaystyle \widetilde{\text{St}}\
\frac{{\rm d}\bm{U}}{{\rm d}t}$ $\displaystyle =$ $\displaystyle -\bm{U}+\bm{V}
,$ (2.16)
$\displaystyle \frac{{\rm d}\bm{x}}{{\rm d}t}$ $\displaystyle =$ $\displaystyle \bm{U}
,$ (2.17)

where $ \widetilde{\text{St}}$ is the effective Stokes number representing the inertial effect of the particle, $ \bm{U}$ is the particle velocity, and $ \bm{V}$ is the terminal velocity obtained by the mobility (or mixed) problem in this case given by

$\displaystyle \bm{V} = \bm{M}\cdot\bm{F}_{\text{ext}} .$ (2.18)

The parameter ``stokes'' in the initialization script corresponds to $ \widetilde{\text{St}}$.

In this dynamics, collisions among particles are implemented not by the contact force but by the momentum exchange for the contact pairs. The frequency of the contact-check is controlled by the parameter ``ncol''.



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Kengo Ichiki 2008-10-12 SourceForge.net Logo Free counter and web stats