Analysis of the gas-solid two-phase flow characteristics and the impact of key structural parameters on the separation performance of medium-speed coal mills

IF 5.7 2区工程技术 Q2 COMPUTER SCIENCE, INTERDISCIPLINARY APPLICATIONS

Advances in Engineering Software Pub Date : 2025-02-26 DOI:10.1016/j.advengsoft.2025.103896

Hailiang Hu, Yiming Li, Hanguang Jin, Biaobiao Lin, Guiqiu Song

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引用次数: 0

Abstract

The EM-type medium-speed mill (EM mill) integrates the functions of crushing, conveying, drying, and separating. It is widely used for grinding coal powder and ores. The mill operates in a "black box" environment, where the internal conditions cannot be easily observed. Due to the limitations of the measurement technology and real-time monitoring, describing the complex particle motion within the mill is challenging. Furthermore, the mill has a complex structure, generating large eddies within the grinding chamber that are difficult to completely remove. This often results in non-compliant coal powder fineness and "over-grinding" phenomena, which significantly affect the production efficiency. This paper conducts numerical simulations using computational fluid dynamics (CFD) and powder classification methods, in order to study the particle motion characteristics and improve the internal flow field distribution of the mill. This allows to increase the particle transport and separation efficiency. These are then compared with experimental results, showing an error of less than 5 %, which demonstrates that the adopted model accurately predicts the flow characteristics and separation performance of the EM mill. Afterwards, the particle motion inside the mill is analyzed based on the coupling method of Fluent 2022R2 and EDEM 2022. Finally, the impacts of the height of the ash bucket cone and the number of separator blades on the internal flow field distribution and particle separation performance are studied. The obtained results show that the particle motion is significantly affected by the flow field. In addition, the increase of the number of separator blades results in reducing the vortex flow between them in a certain range, which significantly improves the coal powder fineness, at the expense of the high discharge of large particles. The reduction of the height of the ash bucket cone limits the generation of vortex flow in the secondary separation zone, which significantly increases the separation efficiency of the coal powder. This study provide valuable guidance for changing the ash bucket structure and adjusting the number of separator blades, and serves as a reference for improving the separation performance of particles and enhancing the internal flow field in EM mill.

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中速磨煤机气固两相流特性及关键结构参数对分离性能的影响分析

EM型中速磨（EM磨）集破碎、输送、干燥、分离等功能于一体。广泛用于粉碎煤粉和矿石。该工厂在一个“黑箱”环境中运行，内部条件不容易观察到。由于测量技术和实时监测的限制，描述磨机内复杂的颗粒运动具有挑战性。此外，磨机结构复杂，在磨腔内产生较大的涡流，难以完全去除。这往往导致煤粉细度不合规和“过磨”现象，严重影响生产效率。本文采用计算流体动力学（CFD）和粉末分级方法进行数值模拟，研究颗粒运动特性，改善磨机内部流场分布。这可以提高颗粒传输和分离效率。与实验结果进行了比较，误差小于5%，表明所采用的模型能够准确地预测电磁磨机的流动特性和分离性能。然后，基于Fluent 2022R2和EDEM 2022的耦合方法，对磨内颗粒运动进行了分析。最后，研究了灰斗锥高度和分离器叶片数对内部流场分布和颗粒分离性能的影响。结果表明，流场对颗粒运动有显著影响。此外，分离器叶片数量的增加使它们之间的涡流在一定范围内减小，从而显著提高了煤粉细度，但牺牲了大颗粒的高排出量。灰斗锥高度的降低限制了二次分选区涡流的产生，显著提高了煤粉的分选效率。该研究为改变灰斗结构和调整分离器叶片数量提供了有价值的指导，为提高EM磨颗粒的分离性能和增强内部流场提供了参考。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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来源期刊

Advances in Engineering Software 工程技术-计算机：跨学科应用

CiteScore

7.70

自引率

4.20%

发文量

169

审稿时长

37 days

期刊介绍： The objective of this journal is to communicate recent and projected advances in computer-based engineering techniques. The fields covered include mechanical, aerospace, civil and environmental engineering, with an emphasis on research and development leading to practical problem-solving. The scope of the journal includes: • Innovative computational strategies and numerical algorithms for large-scale engineering problems • Analysis and simulation techniques and systems • Model and mesh generation • Control of the accuracy, stability and efficiency of computational process • Exploitation of new computing environments (eg distributed hetergeneous and collaborative computing) • Advanced visualization techniques, virtual environments and prototyping • Applications of AI, knowledge-based systems, computational intelligence, including fuzzy logic, neural networks and evolutionary computations • Application of object-oriented technology to engineering problems • Intelligent human computer interfaces • Design automation, multidisciplinary design and optimization • CAD, CAE and integrated process and product development systems • Quality and reliability.