Abstract
Objective: To optimize the operating parameters of wheat milling in roller mill I skin mill to reduce the energy consumption of milling. Methods: Using EDEM discrete element simulation software, Box-Behnken test was designed for key milling factors such as roll pitch, feeding amount, rotational speed and rotational speed ratio to investigate the relationship between operating parameters and milling power. Results: The significance rankings of the effects on the toothed roll crushing power were, in order, speed ratio, roll pitch, feed volume, speed ratio quadratic term, roll pitch quadratic term, interaction of roll pitch and speed ratio, interaction of feed volume and speed ratio, and interaction of roll pitch and feed volume. According to the different requirements of the I-skin mill, the optimal parameter combinations were obtained: the finer powder output with a rolling pitch of 0.67 mm, a feeding amount of 803.60 kg/(cm·d), a fast roller speed of 537.68 r/min, and a rotational speed ratio of 2.64, and the coarser powder output with the optimal low-power consumption of 0.79 mm, a feeding amount of 803.83 kg/(cm·d), a fast roller speed of 576.08 r/min, and a rotational speed ratio of 2.23. Conclusion: The error between the simulation results and the measured results is within a reasonable range, and the established discrete element milling model can be used for power prediction in wheat milling.
Publication Date
4-30-2024
First Page
104
Last Page
109
DOI
10.13652/j.spjx.1003.5788.2023.80458
Recommended Citation
Qifeng, ZHAO; Wenbin, WU; Xuefeng, WANG; and Huapo, JIA
(2024)
"Research on the tooth roll power of roller mill based on discrete element,"
Food and Machinery: Vol. 40:
Iss.
3, Article 15.
DOI: 10.13652/j.spjx.1003.5788.2023.80458
Available at:
https://www.ifoodmm.cn/journal/vol40/iss3/15
References
[1] 黄奇鹏, 武文斌, 高杨杨, 等. 磨粉机磨辊磨损对制粉影响研究综述[J]. 粮食加工, 2020, 45(5): 4-7.
HUANG Q P, WU W B, GAO Y Y, et al. Review of the impact roller wear on the milling process[J]. Grain Processing, 2020, 45(5): 4-7.
[2] 张克平, 谭成, 张锋伟. 基于Fluent的小麦辊式制粉流场模拟及试验验证[J]. 中国粮油学报, 2016, 31(7): 11-18.
ZHANG K P, TAN C, ZHANG F W. Fluent-based simulation and experimental validation of wheat roller milling flow field[J]. Chinese Journal of Cereals and Oils, 2016, 31(7): 11-18.
[3] 廖庆喜, 舒彩霞, 田波平. 辊式磨粉机对辊工作力学条件分析[J]. 包装与食品机械, 2005(2): 1-3, 26.
LIAO Q X, SHU C X, TIAN P P. Analysis of working mechanical conditions of roller mill rolls[J]. Packaging and Food Machinery, 2005(2): 1-3, 26.
[4] TAKAMASA M, TAKESHI F, YOSHIO I. Study on wheat grinding and performance of grinding roll[J]. Jouranal of the Japanese Society of Agriccultural Machinery, 2001, 63(4): 67-72.
[5] 黄奇鹏, 武文斌, 李聪, 等. 磨粉机磨辊齿型参数与功耗关系研究[J]. 粮油食品科技, 2019, 27(1): 30-33.
HUANG Q P, WU W B, LI C, et al. Study on the relationship between grinding mill roll tooth parameters and power consumption[J]. Grain Oil and Food Science and Technology, 2019, 27(1): 30-33.
[6] FANG C, CAMPBELL G M. Roller mill performance prediction IV: The effect of roll configuration on the particle size distribution of wheat initial breakage[J]. Journal of Cereal Science, 2003, 37(1): 21-29.
[7] KALIRAMESH S, KINGSLY A. Predicting particle separation and sieve blinding during wheat flour sifting[J]. Transactions of the Asabe, 2021, 64(3): 1 103-1 112.
[8] 张文龙, 武文斌, 吕少杰, 等. 制粉中的小麦力学参数和接触参数试验标定[J]. 河南工业大学学报(自然科学版), 2023, 44(2): 105-112.
ZHANG W L, WU W B, LU S J, et al. Experimental calibration of mechanical and contact parameters of wheat in flour milling[J]. Journal of Henan University of Technology (Natural Science Edition), 2023, 44(2): 105-112.
[9] 刘海涛, 张炜, 马军民, 等. 青贮玉米饲料籽粒破碎装置仿真分析与试验[J]. 中国农机化学报, 2021, 42(8): 32-39.
LIU H T, ZHANG W, MA J M, et al. Simulation analysis and experiment of corn silage seed crushing device[J]. Chinese Journal of Agricultural Chemistry, 2021, 42(8): 32-39.
[10] 阮竞兰, 武文斌. 粮食机械原理及应用技术[M]. 北京: 机械工业出版社, 2017: 122-153.
RUAN J L, WU W B. Principle and application technology of grain machinery[M]. Beijing: Machinery Industry Press, 2017: 122-153.
[11] 瑞月. 圆锥破碎机工作机理及性能优化研究[D]. 北京: 北京科技大学, 2020: 1-6.
RUI Y. Research on the working mechanism and performance optimization of cone crusher[D]. Beijing: University of Science and Technology Beijing, 2020: 1-6.
[12] QUIST J, EVERTSSON C A. Cone crusher modelling and simulation using DEM[J]. Minerals Engineering, 2016, 85: 92-105.
[13] LINDQVIST M. Energy considerations in compressive and impact crushing of rock[J]. Minerals Engineering, 2008, 21(9): 631-641.
[14] LIU G S, DAI J C, WANG P, et al. Study of railroad ballast crushing parameters based on discrete element method[J]. Journal of Zhejiang University-Science A (Applied Physics & Engineering), 2023, 24(3): 257-272.
[15] JIANG E B, SHAN Z D, CHENG G, et al. Simulation and experimental research on extra-squeeze forming method during gradient sand molding[J]. China Foundry, 2022, 19(4): 288-298.
[16] 张瑞新, 刘煜, 郑群飞, 等. 基于EDEM的双齿辊破碎机破碎效率影响因素仿真分析[J]. 金属矿山, 2018(2): 154-159.
ZHANG R X, LIU Y, ZHENG Q F, et al. Simulation analysis of factors influencing crushing efficiency of double tooth roll crusher based on EDEM[J]. Metal Mining, 2018(2): 154-159.
[17] SUN K K, MA R D, LI G, et al. The influence of the structure of double toothed roller crusher on the crushing effect based on EDEM[J]. IOP Conference Series: Materials Science and Engineering, 2018, 423(1): 012152.
[18] 刘进, 马立峰, 王志霞, 等. 基于EDEM的旋回破碎机能耗模型研究[J]. 煤炭工程, 2023, 55(2): 152-157.
LIU J, MA L F, WANG Z X, et al. Study on energy consumption model of gyratory crusher based on EDEM[J]. Coal Engineering, 2023, 55(2): 152-157.
[19] 文书明, 刘建, 李成必, 等. 矿石碎磨能耗数学模型[J]. 中南大学学报(自然科学版), 2018, 49(9): 2 115-2 120.
WEN S M, LIU J, LI C B, et al. Mathematical model for energy consumption of ore crushing and grinding[J]. Journal of Central South University (Natural Science Edition), 2018, 49(9): 2 115-2 120.