BP神经网络预测变振幅防堵筛分性能研究——基于EDEM-RecurDyn仿真

doi:10.13733/j.jcam.issn.2095-5553.2022.11.012

摘要/Abstract

摘要： 针对物料喂入量变化导致振动筛面堆积堵塞，影响筛分性能的问题。以变振幅筛分机构导向滑槽转角为变量，RecurDyn和EDEM联合仿真水稻籽粒、茎秆非正常喂入(0.5 kg/s)条件下变振幅防堵筛分过程。BP神经网络预测不同滑槽转角下变振幅的筛分效率、含杂率，优化变振幅调节，缓解筛面堆积堵塞，改善筛分性能。结果表明物料非正常喂入(0.5 kg/s)下导向滑槽转角0°~10°时筛分效率在55%~58%内平稳上升，含杂率在0.1%~0.16%内小范围波动变化；滑槽转角15°~40°时筛分效率在58%~75%内线性增大，含杂率在0.11%~0.19%内波动上升；滑槽转角40°~45°时筛分效率骤然线性下降至65.8%，含杂率陡然升高至0.37%。BP神经网络预测滑槽转角在37°时变振幅筛分效率最高、含杂率较低，变振幅防堵筛分性能更好，此时筛分效率和含杂率为74.30%、0.20%。BP神经网络预测模型R2为0.999，预测误差集中在-0.000 41，预测曲线均高度拟合。验证了BP神经网络预测模型的可靠性和精确度。这为未来变振幅防堵筛分的智能化调控提供了依据。

关键词: 变振幅, EDEM-RecurDyn, BP神经网络, 筛分效率, 含杂率

Abstract:

Aiming at the problem that the vibrating screen surface is blocked due to the change of material feeding amount, which affects the screening performance, the angle of the guide chute for the variable amplitude screening mechanism as the variable, the variable amplitude antiblocking screening process under abnormal feeding of rice grains and stems (0.5 kg/s as an example) was simulated by RecurDynEDEM. BPNN was used to accurately predict the variable amplitude screening efficiency and impurity content for different chute angles, and optimized the parameters for the variable amplitude screen, to alleviate the accumulation and blockage on the screen surface and improve the screening performance. The results showed that under the abnormal feeding (0.5 kg/s), the screening efficiency increased steadily within 55% - 58% when the guide chute angle was 0°-10°, the impurity content fluctuated in a small range within 0.1%-0.16%, the screening efficiency increased linearly within 58%-75% when the chute angle was 15°-40°, the impurity content fluctuated and increased within 0.11%-0.19%, and the screening efficiency suddenly decreased linearly to 658% when the chute angle was 40°-45°, the impurity content increased sharply to 0.37%. BP neural network predicted that the variable amplitude screening efficiency was the highest, the impurity content was low, and the variable amplitude antiblocking screening performance was better, when the chute angle was 37°. The screening efficiency and impurity content were 74.30% and 020%. The R2 of BP neural network prediction model was 0999, the prediction error was concentrated at -0.000 41, and the prediction curves were highly fitted, which verified the reliability and accuracy. This provides a basis for the intelligent adjustment of variable amplitude antiblocking screening in the future.

Key words: variable amplitude, EDEM-RecurDyn, BP neural network, screening efficiency, impurity content

中图分类号:

朱永乐, 马征, 陈树人, Souleymane Nfamoussa Traore, 李耀明, 姜晟, . BP神经网络预测变振幅防堵筛分性能研究——基于EDEM-RecurDyn仿真[J]. 中国农机化学报, 2022, 43(11): 75-80.

Zhu Yongle, Ma Zheng, Chen Shuren, Souleymane Nfamoussa Traore, Li Yaoming, Jiang Sheng.. Study on BPNN prediction of variable amplitude antiblocking screening performance: Based on EDEM-RecurDyn simulation [J]. Journal of Chinese Agricultural Mechanization, 2022, 43(11): 75-80.

参考文献

［1］　
郭红星, 金诚谦, 印祥, 等. 谷物联合收获机清选系统研究现状［J］. 中国农机化学报, 2020, 41(6): 26-36.

Guo Hongxing, Jin Chengqian, Yin Xiang, et al. Research status of the cleaning system of the corn combine harvester ［J］. Journal of Chinese Agricultural Mechanization, 2020, 41(6): 26-36.

［2］　
Ma Zheng, Li Yaoming, Xu Lizhang. Discreteelement method simulation of agricultural particles motion in variableamplitude screen box ［J］. Computers and Electronics in Agriculture, 2015, 118（2）: 92-99.

［3］　
曾智伟, 马旭, 曹秀龙, 等. 离散元法在农业工程研究中的应用现状和展望［J］. 农业机械学报, 2021, 52(4): 1-20.

Zeng Zhiwei, Ma Xu, Cao Xiulong, et al. Critical review of applications of discrete element method in agricultural engineering ［J］. Transactions of the Chinese Society for Agricultural Machinery, 2021, 52(4): 1-20.

［4］　
李磊. 离散元法在农业工程中的研究现状及展望［J］. 中国农机化学报, 2015, 36(5): 345-348.

Li Lei. Research progress and prospects of DEM in agricultural engineering application ［J］. Journal of Chinese Agricultural Mechanization, 2015, 36(5): 345-348.

［5］　
邓佳玉, 胡军, 李庆达, 等. 基于EDEM离散元法的深松铲仿真与试验研究［J］. 中国农机化学报, 2016, 37(4): 14-18.

Deng Jiayu, Hu Jun, Li Qingda, et al. Simulation and experimental study on the subsoiler based on EDEM discrete element method ［J］. Journal of Chinese Agricultural Mechanization, 2016, 37(4): 14-18.

［6］　
马征, 李耀明, 徐立章. 农业工程领域颗粒运动研究综述［J］. 农业机械学报, 2013, 44(2): 22-29.

Ma Zheng, Li Yaoming, Xu Lizhang. Summarize of particle movements research in agricultural engineering realm ［J］. Transactions of the Chinese Society for Agricultural Machinery, 2013, 44(2): 22-29.

［7］　
张晓宇. 质心偏移变振幅振动筛筛分机理研究及设备设计［D］. 济南: 山东大学, 2020.

Zhang Xiaoyu. Scireening mechanism and equipment design of variable amplitude vibarting screen with mass center offset ［D］. Jinan: Shandong University, 2020.

［8］　
黄龙, 潘淼, 江海深, 等. 变振幅等厚筛分过程中生产率对粒群时空分布与分级效果的影响研究［J］. 选煤技术, 2019, (3): 23-29.

Huang Long, Pan Miao, Jiang Haishen, et al. A study of the effects on temporal and spatial distribution of particle groups and sizing effect produced by productivity in variableamplitude equal bedthickness screening process［J］. Coal Preparation Technology, 2019, (3): 23-29.

［9］　
Qiao Jinpeng, Duan Chenlong, Jiang Haishen, et al. Research on screening mechanism and parameters optimization of equal thickness screen with variable amplitude based on DEM simulation［J］. Powder Technology, 2018, 331: 296-309.

［10］　
傅隆生, 宋珍珍, Zhang Xin, 等. 深度学习方法在农业信息中的研究进展与应用现状［J］. 中国农业大学学报, 2020, 25(2): 105-120.

Fu Longsheng, Song Zhenzhen, Zhang Xin, et al. Applications and research progress of deep learning in agriculture ［J］. Journal of China Agricultural University, 2020, 25(2): 105-120.

［11］　
姬鹏飞, 孟伟娜, 杨北方, 等. 基于改进BP神经网络的农业机械数据预测研究［J］. 中国农机化学报, 2020, 41(2): 200-205.

Ji Pengfei, Meng Weina, Yang Beifang, et al. Research on prediction of the number of agricultural machinery data based on an improving method of BP neural network ［J］. Journal of Chinese Agricultural Mechanization, 2020, 41(2): 200-205.

［12］　
Sawomir Francik, Zbigniew S＇lipek, Jarosaw Frczek, et al. Present trends in research on application of artificial neural networks in agricultural engineering ［J］. Agricultural Engineering, 2016, 20(4): 15-25.

［13］　
朱会霞, 刘凤超, 李彤煜, 等. 改进的遗传神经网络算法对花生种子带式清选设备关键作业参数的优化［J］. 花生学报, 2019, 48(3): 55-59.

Zhu Huixia, Liu Fengchao, Li Tongyu, et al. Optimization of key working parameters of belt separator for peanut seeds by improved genetic neural network ［J］. Journal of Peanut Science, 2019, 48(3): 55-59.

［14］　
Yang Xiaodong, Wu Jida, Jiang Haishen, et al. Dynamic modeling and parameters optimization of large vibrating screen with full degree of freedom ［J］. Shock and Vibration, 2019.

［15］　
宋宝成, 刘初升, 程杰, 等. 基于神经网络与DEM技术的湿磷矿石筛分参数优化［J］. 化工矿物与加工, 2016, 45(9): 6-8.

Song Baocheng, Liu Chusheng, Cheng Jie, et al. Optimization of parameters for wet phosphate rock screening based on neural network and DEM technology ［J］. Industrial Minerals & Processing, 2016, 45(9): 6-8.

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