CFD Study of the Gas-particle Flow in a Horizontal Duct: The Impact of the Solids Wall Boundary Conditions Article Swipe

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Mechanics Boundary value problem Solver Surface finish Physics Law of the wall Surface roughness Specularity Classical mechanics Geometry Materials science Mathematics Mathematical analysis Reynolds number Engineering Optics Thermodynamics Mechanical engineering Specular reflection Turbulence Mathematical optimization

Afsaneh Soleimani , Simon Schneiderbauer , Stefan Pirker ·

YOU? · · 2015 · Open Access · · DOI: https://doi.org/10.1016/j.proeng.2015.01.225 · OA: W2070121874

The Johnson-Jackson boundary conditions are included in the twoPhaseEulerFoam solver of OpenFOAM-2.2.x in order to consider the wall-friction effect on the movement of particles. A straight conveying line using Johnson-Jackson boundary conditions is simulated. The results show that the particles' velocity at the wall is in better agreement with the experimental results [1], compared to the results of the original solver neglecting wall-friction. However, the model is valid only for a specific adjusted value of the specularity coefficient. Thus, Johnson-Jackson model is revisited based on the work of Li and Benyahia [2]. To improve the accuracy of the granular temperature contribution, a new boundary condition, which incorporates sliding and non-sliding collisions, proposed by Schneiderbauer et al. [3], is included in the solver. The velocity profiles of the particles, using the latter boundary conditions, are compared to that of the Johnson-Jackson cases as well as the experimental results. It appears that the boundary conditions of Schneiderbauer et al. [3] yield better agreement with experimental data since these are based on the physical properties and incorporate the coulomb limit to particle-wall collision. Furthermore, based on the experimental study of Sommerfeld and Kussin [1], wall-roughness appears to be an important factor for the transfer of tangential momentum in vertical direction. Accordingly, wall-roughness and shadow effect [4] are studied in order to propose a new model for including wall-roughness in TFM simulations. Finally, the proposed model is implemented in twoPhaseEulerFoam, and the effect of this phenomenon on the particle's velocity profile is studied. The results show that wall-roughness has a strong effect on rebound and redispersion of the particles and accordingly changes the particles' concentration in the section of conveying line significantly.