BP neural network model for material distribution prediction based on variable amplitude anti-blocking screening DEM simulations

Zheng Ma, Yongle Zhu, Zhiping Wu, Souleymane Nfamoussa Traore, Du Chen, Licheng Xing

Abstract


The material feeding changing of combine harvester is easy to cause accumulation and blockage of the vibrating screen, which seriously affects the harvest operation. In order to alleviate such accumulation and blockages on the vibrating screen surface, the guide chute rotation angle of the improved variable amplitude screening mechanism was selected as the target variable, and EDEM-RecurDyn was employed to simulate the anti-blocking process of the variable amplitude under a changing feeding quantity (0.5 kg/s abnormal, 0.2 kg/s normal) of materials (rice grain and stem mixture). A BP (an error back propagation algorithm) neural network was designed and the prediction model of the material distribution was subsequently constructed on the variable screening surface under different chute angles during abnormal feeding. The results revealed a continuous decrease in the quality and time of the material blockage at the front end of the screen surface with the increasing guide chute angle. At the guide chute angle of 20°-45° and adjustment time of 3-6 s, the blocked and accumulated materials at the front-end screen surface was be moved back to Grid 6 for screening. However, overtime, the screen surface materials continued to move back under the chute angle of 40°-45°, which had a great impact on the screening performance. At the guide chute angle of 30°-35° and adjustment time of 4 s, the materials on the screen surface were evenly distributed in Grid 1-6. This was able to alleviate the accumulation and blockage of the screen surface materials. The R of the material distribution prediction model (BP neural network) on the screen surface was determined as 0.97, indicating the high reliability and accuracy of the material distribution model on the screen surface based on the BP neural network. This work provides an important reference for the variable amplitude intelligent control of screen surface material anti-blocking.
Keywords: variable amplitude, material distribution, EDEM-RecurDyn, BP neural network
DOI: 10.25165/j.ijabe.20231604.7178

Citation: Ma Z, Zhu Y L, Wu Z P, Traore S N, Chen D, Xing L C. BP neural network model for material distribution prediction based on variable amplitude anti-blocking screening DEM simulations. Int J Agric & Biol Eng, 2023; 16(4): 191-200

Keywords


variable amplitude, material distribution, EDEM-RecurDyn, BP neural network

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References


Wang L J, Song L L, Feng X, Wang H S, Li Y H. Research status and development analysis of screening devices of grain combine harvester. Transactions of the CSAM, 2021; 52(6): 1-17.

Li H B, Zhao X Q, Geng K H. Design and analysis on configuration of a multiple DOF and rigid-flexible coupling sieving machine. Mining & Processing Equipment, 2020; 48(4): 46-50. (in Chinese)

Chang J, Wang C J, Hu Z B, Han D D, Chen L. Design of a variable degree of freedom parallel vibration sieve. Mechanical Engineering & Automation, 2015; (4): 97-99+102. (in Chinese)

Li J. Research of three-dimensional parallel vibration screen for grain cleaning. PhD dissertation, Zhenjiang: Jiangsu University, 2013; 133p. (in Chinese)

Bao C Y. Study on vibrating screening process mechanism basing on DEM. MA thesis. Xuzhou: China University of Mining and Technology, 2016; 96p. (in Chinese)

Wang Z Y, Ren N, Wu W B, Li Y X. Research on screening results of reciprocating vibration screen based on discrete element method. Journal of Agricultural Mechanization Research, 2016; 38(1): 33-38. (in Chinese)

Ma Z, Li Y M, Xu L Z. Discrete-element method simulation of agricultural particles’ motion in variable-amplitude screen box. Computers and Electronics in Agriculture, 2015; 118: 92-99.

Zeng Z W, Ma X, Cao X H, Li Z H, Wang X C. Critical review of applications of discrete element method in agricultural engineering. Transactions of the CSAM, 2021; 52(4): 1-20. (in Chinese)

Ma Z, Li Y M, Xu L Z, Chen J, Zhao Z, Tang Z. Dispersion and migration of agricultural particles in a variable-amplitude screen box based on the discrete element method. Computers and Electronics in Agriculture, 2017; 142: 173-180.

Li H, Wang J S, Yuan J B, Yin W Q, Wang Z M, Qian Y Z. Analysis of threshed rice mixture separation through vibration screen using discrete element method. Int J Agric & Biol Eng, 2017; 10(6): 231-239.

Ma X D, Zhao L, Guo B, Dang H. Simulation and experiment of rice cleaning in air-separation device based on DEM-CFD coupling method. Int J Agric & Biol Eng, 2020; 13(5): 226-233.

Wu X J, Li S Y, Fang P, Xi Z J, Hou Y J, Liu Y P. Particle migration DEM simulation of shale shaker under different screen surface shape. Mechanical Research & Application, 2017; 30(5): 45-49. (in Chinese)

Harzanagh A A, Orhan E C, Ergun S L. Discrete element modelling of vibrating screens. Minerals Engineering, 2018; 121: 107-121.

Van Xo N, Linh N K. Applications of Discrete Element Method (DEM) in modeling the impact of dynamic and technological parameters on the material movement on the vibrating screen surface//IOP Conference Series: Materials Science and Engineering. IOP Publishing, 2020; 843(1): 012024.

Xu Y F, Zhang X L, Wu S, Chen C, Wang J Z, Yuan S Q, et al. Numerical simulation of particle motion at cucumber straw grinding process based on EDEM. Int J Agric & Biol Eng, 2020; 13(6): 227-235.

Zhang J, Liu F Y, Chen J. Virtual vibration screening experiments of grain cleaning sieve based on DEM. Journal of Agricultural Mechanization Research, 2019; 41(2): 187-191. (in Chinese)

Ji L L, Xie H X, Yang H G, Wei H, Yan J C, Shen H Y. Simulation analysis of potato dry soil cleaning device based on EDEM-RecurDyn coupling. Journal of Chinese Agricultural Mechanization, 2021; 42(1): 109-115. (in Chinese)

Wen P F, Qiao J P, Duan C L, Jiang H S, Zhao Y M. Research on Screening Behavior and Distribution of Materials during Variable Amplitude Equal Thickness Screening. Coal Mine Machinery, 2020; 41(4): 165-167. (in Chinese)

Jiang H S. Research on the Mechanism of Variable-amplitude Equal-thickness Elastic Deep Screening of Moist Coal. Xuzhou: China University of Mining and Technology, 2017; 166 p. (in Chinese)

Zhu N Y, Liu X, Liu Z Q, Hu K, Wang Y K, Tan J L, et al. Deep learning for smart agriculture: Concepts, tools, applications, and opportunities. Int J Agric & Biol Eng, 2018; 11(4): 32-44. doi: 10.25165/j.ijabe.20181104.4475.

Huang Y B. Research status and applications of nature-inspired algorithms for agri-food production. Int J Agric & Biol Eng, 2020; 13(4): 1-9. doi: 10.25165/j.ijabe.20201304.5501.

Zhang Q. Research and application of BP neural network in agricultural engineering. Agricultural Engineering, 2012; 2(5): 17-20. (in Chinese)

Wang J Q. Research on BP neural network theory and its application in agricultural mechanization. PhD dissertation, Shenyang: Shenyang Agricultural University, 2011; 115p. (in Chinese)

Hu J, Xin P P, Zhang S W, Zhang H H, He D J. Model for tomato photosynthetic rate based on neural network with genetic algorithm. Int J Agric & Biol Eng, 2019; 12(1): 179-185. doi: 10.25165/j.ijabe.20191201.3127.

Li T, Zhang M, Ji Y H, Sha S, Jiang Y Q, Li M Z. Management of CO2 in a tomato greenhouse using WSN and BPNN techniques. Int J Agric & Biol Eng, 2015; 8(4): 43-51. doi: 10.3965/j.ijabe.20150804.1572.

Feng X B, He P J, Zhang H X, Yin W Q, Qian Y, Cao P, et al. Rice seeds identification based on back propagation neural network model. Int J Agric & Biol Eng, 2019; 12(6): 122-128. doi: 10.25165/j.ijabe.20191206.5044.

Shanmugam B K, Vardhan H, Raj M G, Kaza M, Sah R, Hanumanthappa H. Artificial neural network modeling for predicting the screening efficiency of coal with varying moisture content in the vibrating screen. International Journal of Coal Preparation and Utilization, 2021; 1-19.

Li X, Sun X Y, Li L Y. Optimization design of angular velocity control of threshing cylinder in combine harvester based on wavelet neural network. Journal of Agricultural Mechanization Research, 2016; 38(11): 64-68. (in Chinese)

Ge Y S, Zhou D D, Xu R. Research on loss detection of combine harvester based on neural network. Journal of Nanjing Institute of Technology (Natural Science Edition), 2018; 16(2): 57-61. (in Chinese)

Song B C, Liu C S, Cheng J, Hu M. Optimization of parameters for wet phosphate rock screening based on neural network and DEM technology. Industrial Minerals & Processing, 2016; 45(9): 6-8. (in Chinese)

Zhao Z, Jin M Z, Qin F, Yang S X. A novel neural network approach to modeling particles distribution on vibrating screen. Powder Technology, 2021; 382: 254-261.

Kim K C, Jiang T, Kim N I, Kwon C. Effects of ball-to-powder diameter ratio and powder particle shape on EDEM simulation in a planetary ball mill. Journal of the Indian Chemical Society, 2022; 99 (1): 100300.

Ma L R, Cao S K, Zhong W Z, Song X W, Shen H. Simulation research on operation parameters of cleaning device based on EDEM. Agricultural Technology & Equipment, 2017; 7: 80-83. (in Chinese)

Li H C. Theoretical and Experimental Study on Air -and -screen Cleaning Unit. PhD dissertation. Zhenjiang: Jiangsu University. 2011; 119p. (in Chinese)

Zhang C, Guo Y, Li M. Review of development and application of artificial neural network models. Computer Engineering and Applications, 2021; 57(11): 57-69. (in Chinese)




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