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Numerical Simulation and Experimental Study of Corn Straw Grinding Process Based on Computational Fluid Dynamics–Discrete Element Method

Author

Listed:
  • Xin Wang

    (College of Mechanical and Electrical Engineering, Inner Mongolia Agricultural University, Hohhot 010010, China)

  • Haiqing Tian

    (College of Mechanical and Electrical Engineering, Inner Mongolia Agricultural University, Hohhot 010010, China)

  • Ziqing Xiao

    (College of Mechanical and Electrical Engineering, Inner Mongolia Agricultural University, Hohhot 010010, China)

  • Kai Zhao

    (College of Mechanical and Electrical Engineering, Inner Mongolia Agricultural University, Hohhot 010010, China)

  • Dapeng Li

    (Changzhou College of Information Technology, Changzhou 213164, China)

  • Di Wang

    (Changzhou Vocational Institute of Mechatronic Technology, Changzhou 213164, China)

Abstract

To improve the operational efficiency of a hammer mill and delve into a high-efficiency, energy-saving grinding mechanism, the crucial parameters influencing the grinding of corn straw were identified as the spindle speed, hammer–sieve gap, and sieve pore diameter. According to the force analysis and kinematics analysis, the key factors affecting corn straw grinding were the spindle speed, the hammer–sieve gap, and the sieve pore diameter. The grinding process of corn straw was studied using computational fluid dynamics (CFDs) and the discrete element method (DEM) gas–solid coupling numerical simulation and experiment. The numerical simulation results showed that with the growth of time, the higher the spindle speed, the faster the bonds broke in each part, and the higher the grinding efficiency. When the energy loss of the hammer component was in the range of 985.6~1312.2 J, and the total collision force of the corn straw was greater than 47,032.5 N, the straw grinding effect was better, and the per kW·h yield was higher. The experimental results showed that the optimum combination of operating parameters was a spindle speed of 2625 r/min, a hammer-screen gap of 14 mm, and a sieve pore diameter of 8 mm. Finally, the CFD–DEM gas–solid coupling numerical simulation validation tests were performed based on the optimal combination of the operating parameters. The results showed that the energy loss of the hammer component was 1189.5 J, and the total collision force of the corn straw was 49,523.5 N, both of which were within the range of better results in terms of numerical simulation. Thus, the CFD–DEM gas–solid coupling numerical simulation could accurately predict the corn straw grinding process. This study provides a theoretical basis for improving a hammer mill’s key components and grinding performance. Meanwhile, the proposed gas–solid two-phase flow method provided theoretical references for other research in agricultural machinery.

Suggested Citation

  • Xin Wang & Haiqing Tian & Ziqing Xiao & Kai Zhao & Dapeng Li & Di Wang, 2024. "Numerical Simulation and Experimental Study of Corn Straw Grinding Process Based on Computational Fluid Dynamics–Discrete Element Method," Agriculture, MDPI, vol. 14(2), pages 1-19, February.
    • Handle: RePEc:gam:jagris:v:14:y:2024:i:2:p:325-:d:1341016
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    Citations

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    Cited by:

    1. Chunrong Li & Zhounan Liu & Ligang Geng & Tianyue Xu & Weizhi Feng & Min Liu & Da Qiao & Yang Wang & Jingli Wang, 2025. "The Establishment of a High-Moisture Corn Ear Model Based on the Discrete Element Method and the Calibration of Bonding Parameters," Agriculture, MDPI, vol. 15(7), pages 1-22, March.
    2. Man Gu & Haiyang Shen & Weiwen Luo & Jie Ling & Bokai Wang & Fengwei Gu & Shumin Song & Liang Pan & Zhichao Hu, 2025. "Calibration of Parameters for Leaf-Stem-Cutting Model of Tuber Mustard ( Brassica juncea L.) Based on Discrete Element Method," Agriculture, MDPI, vol. 15(7), pages 1-19, April.
    3. Tianyue Xu & Yan Gou & Dongyan Huang & Jianqun Yu & Chunrong Li & Jingli Wang, 2024. "Modeling and Parameter Selection of the Corn Straw–Soil Composite Model Based on the DEM," Agriculture, MDPI, vol. 14(11), pages 1-18, November.

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