期刊
PARTICUOLOGY
卷 88, 期 -, 页码 107-115出版社
ELSEVIER SCIENCE INC
DOI: 10.1016/j.partic.2023.08.018
关键词
Discrete element method; Die filling; Forced feeding; Stirrer design; GPU computing
This paper analyzes the die filling process using a discrete element method, and evaluates the influence of different stirrer designs on the filling performance. The results show that the helical-ribbon stirrer design exhibits the highest filling ratio and is the most robust design. Furthermore, the stirrer speed and filling speed have an impact on the filling performance.
Die filling is a critical stage during powder compaction, which can significantly affect the product quality and efficiency. In this paper, a forced feeder is introduced attempting to improve the filling performance of a lab-scale die filling system. The die filling process is analysed with a graphics processing units (GPU) enhanced discrete element method (DEM). Various stirrer designs are assessed for a wide range of process settings (i.e., stirrer speed, filling speed) to explore their influence on the die filling performance of free-flowing powder. Numerical results show that die filing with the novel helical-ribbon (i.e., type D) stirrer design exhibits the highest filling ratio, implying that it is the most robust stirrer design for the feeder configuration considered. Furthermore, die filling performance with the type D stirrer design is a function of the stirrer speed and the filling speed. A positive variation of filling ratio (h(f)>0%) can be ensured over the whole range of filling speed by adjusting the stirrer speed (i.e., increasing the stirrer speed). The approach used in this study can not only help understand how the stirrer design affects the die filling performance but also guide the optimization of feeder system and process settings.(c) 2023 Published by Elsevier B.V. on behalf of Chinese Society of Particuology and Institute of Process Engineering, Chinese Academy of Sciences.
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