Euler-like modelling of dense granular flows: application to a rotating drum

B\'ereng\`ere Dubrulle (GIT); Daniel Bonamy (SPCSI); Fran\c{c}ois Daviaud (GIT); Mathieu Renouf (LaMCoS); Pierre-Henri Chavanis (LPT); Pierre Philippe Cortet

arxiv: 0803.0191 · v2 · pith:BQJ5QQLMnew · submitted 2008-03-03 · ❄️ cond-mat.stat-mech

Euler-like modelling of dense granular flows: application to a rotating drum

Daniel Bonamy (SPCSI) , Pierre-Henri Chavanis (LPT) , Pierre Philippe Cortet , Fran\c{c}ois Daviaud (GIT) , B\'ereng\`ere Dubrulle (GIT) , Mathieu Renouf (LaMCoS) This is my paper

classification ❄️ cond-mat.stat-mech

keywords flowsgranulardensedrumequationeulerfunctionsrotating

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General conservation equations are derived for 2D dense granular flows from the Euler equation within the Boussinesq approximation. In steady flows, the 2D fields of granular temperature, vorticity and stream function are shown to be encoded in two scalar functions only. We checked such prediction on steady surface flows in a rotating drum simulated through the Non-Smooth Contact Dynamics method. This result is non trivial because granular flows are dissipative and therefore not necessarily compatible with Euler equation. Finally, we briefly discuss some possible ways to predict theoretically these two functions using statistical mechanics.

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Euler-like modelling of dense granular flows: application to a rotating drum

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