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引用次数: 0
摘要
由于湿颗粒具有较高的可压缩性,因此被广泛应用于各个领域。本研究对湿颗粒压缩进行了有限元法(FEM)模拟,以讨论粘合剂对湿颗粒压缩性的影响。利用压缩和粉末剪切试验获得的参数,将 Drucker-Prager Cap 模型应用于湿颗粒,并使用这些参数进行有限元模拟。结果表明,有限元模拟获得的底面轴向应力和壁面径向应力与大应变区域压缩池的底面和径向(壁面)应力的实验值一致。此外,不同粘合剂用量的湿颗粒的有限元模拟结果表明,粘合剂用量较高的湿颗粒中的颗粒之间的粘附力更强,从而增加了轴向和径向应力。
Finite Element Method Simulation of Wet Granule Compression
Wet granules are used in various areas, owing to their higher compressibility. In this study, finite element method (FEM) simulations of wet granule compression are performed to discuss the influence of binder on the compressibility of wet granules. The Drucker-Prager Cap model was applied to wet granules with parameters obtained from compression and powder shear tests, and the FEM simulation was performed using these parameters. The results showed that the axial stress at the bottom surface and the radial stress of the wall obtained from the FEM simulation were consistent with the experimental values for the bottom and radial (wall) stress of the compression cell in large strain regions. Furthermore, the FEM results for wet granules with different amounts of binder suggested that particles in wet granules with higher amounts of binder adhered each other more strongly, thereby increasing the axial and radial stresses.
期刊介绍:
The Journal of the Society of Powder Technology, Japan publishes valuable research papers in various fields related to powder technology and provides useful information to members. It publishes monthly original research papers and technical papers as well as general articles that are useful for members. It also covers reviews, overseas reports, doctoral thesis introduction and other materials in various fields related to powder technology. It is widely known as the only journal for the members who have keen interest in powder technology.