Leqi Lin , Xin Zhang , Mingzhe Yu , Iqbal M Mujtaba , Xizhong Chen
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引用次数: 0
Abstract
Particle mixing is a crucial operation in various industrial production processes. However, phenomena like segregation or local accumulation can arise, especially when particles differ in properties like radius and density. Numerical simulation of particles using Discrete Element Method (DEM) allows for the manipulation of control variables in batches, generating a large amount of data and facilitating quantitative research. In this study, the mixing behaviors of binary particles in rotating drums are systematically investigated. The DEM model is first validated with experimental data and then rotating drums with varying obstacles, rotation speeds, particle radii, and densities are simulated. Moreover, a Gaussian process-based optimization is conducted by correlating Lacey mixing index (MI) and parameterized shape of obstacle to find the optimized mixing condition. Experimental validations are further performed on the optimized condition to verify the design. It is shown that this integrated approach holds significant potential for enhancing the efficiency, effectiveness of industrial mixing processes and the consideration of energy consumption when balancing the mixing efficiency and optimal rotating speed.
颗粒混合是各种工业生产过程中的一项重要操作。然而,偏析或局部堆积等现象可能会出现,尤其是当颗粒的半径和密度等特性不同时。使用离散元素法(DEM)对颗粒进行数值模拟,可以批量操作控制变量,生成大量数据,便于定量研究。本研究系统地研究了二元颗粒在旋转滚筒中的混合行为。首先用实验数据验证了 DEM 模型,然后模拟了具有不同障碍物、转速、颗粒半径和密度的旋转滚筒。此外,通过将雷西混合指数(MI)与障碍物的参数化形状相关联,进行了基于高斯过程的优化,以找到优化的混合条件。此外,还对优化条件进行了实验验证。结果表明,这种综合方法在提高工业混合过程的效率和效果以及在平衡混合效率和最佳转速时考虑能耗方面具有巨大潜力。
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