Three-dimensional numerical simulation of quasi-static pebble flow

To investigate the influence of drainage rate and the particle contact model on the main features of the pebble flow such as streamline pattern, diffusion of pebbles and velocity profile, the quasi-static pebble flow of full scale German HTR-MODUL pebble bed is performed with up to 360,000 frictiona...

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Bibliographic Details
Published in:Advanced powder technology : the international journal of the Society of Powder Technology, Japan Japan, 2017-02, Vol.28 (2), p.499-505
Main Authors: Sun, X.M., Dong, Y.J., Hao, P.F., Shi, L., Li, F., Feng, Y.T.
Format: Article
Language:English
Subjects:
Discrete element method
Granular flow
Pebble bed
Pebble flow
Sphere packing
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Summary:To investigate the influence of drainage rate and the particle contact model on the main features of the pebble flow such as streamline pattern, diffusion of pebbles and velocity profile, the quasi-static pebble flow of full scale German HTR-MODUL pebble bed is performed with up to 360,000 frictional graphite spheres. It reveals that the quasi-static pebble flow and Hertzian model are optimal choices of neutronic physics design of pebble bed reactor when the residue time of pebbles is particularly concerned. [Display omitted] •A quasi-static pebble flow of full scale German HTR-MODUL pebble bed is performed.•The sphere-wall boundary is analyzed to avoid the underestimate of wall friction.•It reveals the contact models influence the pattern of velocity profiles. To investigate the influence of the drainage rate and the particle contact model on the main features of the pebble flow, a quasi-static pebble flow of full scale German HTR-MODUL pebble bed is performed with up to 360,000 frictional graphite spheres. The treatment of the sphere-wall boundary condition is analyzed to avoid underestimating the friction of pebble near the wall. The streamlines, diffusion of pebbles and velocity profiles of pebble flow are drawn and analyzed. It shows that the streamlines and diffusion of pebbles inside the pebble bed are barely affected by the drainage rate and the particle contact model used. However, it reveals that the drainage rate and the contact model obviously influence the pattern of velocity profiles. It demonstrates that the quasi-static pebble flow and the Hertzian model are optimal choices of the neutronic physical design of the pebble bed reactor when the residue time of pebbles is particularly concerned.
ISSN:0921-8831
1568-5527
DOI:10.1016/j.apt.2016.11.007