Modelling of powder die compaction for press cycle optimization

A new electromechanical press for fuel pellet manufacturing was built last year in partnership between CEA-Marcoule and ChampalleAlcen. This press was developed to shape pellets in a hot cell via remote handling. It has been qualified to show its robustness and to optimize the compaction cycle, thus...

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Bibliographic Details
Published in:EPJ nuclear sciences & technologies 2016-01, Vol.2, p.25
Main Authors: Bayle, Jean-Philippe, Reynaud, Vincent, Gobin, François, Brenneis, Christophe, Tronche, Eric, Ferry, Cécile, Royet, Vincent
Format: Article
Language:English
Subjects:
Axial stress
Computer simulation
Density gradients
Die pressing
Dies
Engineering Sciences
Finite element method
Friction
Kinematics
Lubricants & lubrication
Manufacturing
Materials
Mathematical models
Nuclear reactors
Optimization
Parameters
Pellets
Powder metallurgy
Remote handling
Residual stress
Sintering
Sintering (powder metallurgy)
Stress concentration
Tolerances
Uranium dioxide
Variations
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Summary:A new electromechanical press for fuel pellet manufacturing was built last year in partnership between CEA-Marcoule and ChampalleAlcen. This press was developed to shape pellets in a hot cell via remote handling. It has been qualified to show its robustness and to optimize the compaction cycle, thus obtaining a better sintered pellet profile and limiting damage. We will show you how 400 annular pellets have been produced with good geometry's parameters, based on press settings management. These results are according to a good phenomenological pressing knowledge with Finite Element Modeling calculation. Therefore, during die pressing, a modification in the punch displacement sequence induces fluctuation in the axial distribution of frictional forces. The green pellet stress and density gradients are based on these frictional forces between powder and tool, and between grains in the powder, influencing the shape of the pellet after sintering. The pellet shape and diameter tolerances must be minimized to avoid the need for grinding operations. To find the best parameters for the press settings, which enable optimization, FEM calculations were used and different compaction models compared to give the best calculation/physical trial comparisons. These simulations were then used to predict the impact of different parameters when there is a change in the type of powder and the pellet size, or when the behavior of the press changes during the compaction time. In 2016, it is planned to set up the press in a glove box for UO2 manufacturing qualification based on our simulation methodology, before actual hot cell trials in the future.
ISSN:2491-9292
2491-9292
DOI:10.1051/epjn/2016018