In order to study the movement characteristics and separation mechanism of rice and its impurities under the action of airflow, and lower the impurity rate in the cleaning operation process, rice and its impurities were modeled based on the “overlapping multi-sphere clump method”, the DEM-CFD coupling method was used to simulate rice cleaning process under different airflow velocity and airflow inclined angle, and combined with aerodynamics, the motion state and separation behavior of rice and its impurities in the flow field. The results showed that under horizontal airflow conditions, the average impurity rate of rice was the lowest when the airflow velocity was 9 m/s. When the flow velocity remains unchanged and the airflow inclined angle was set at 10°, the average impurity rate decreased, while the entrainment loss rate increased. The airflow velocity was negatively correlated with the impurity rate and positively correlated with the entrainment loss rate, while the airflow inclined angle was negatively correlated with the impurity rate and positively correlated with the entrainment loss rate. By designing and setting up an experimental device, an experiment was carried out with airflow velocity and airflow inclined angle as the factors, and the experimental results were consistent with the simulation results, indicating that it was reliable to study the physical behavior of rice-straw separation in the airflow field by using the DEM-CFD coupling method.
Keywords: DEM-CFD, rice cleaning, airflow velocity, airflow inclined angle, experiment
DOI: 10.25165/j.ijabe.20201305.5225

Citation: Ma X D, Zhao L, Guo B J, 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.

DEM-CFD, rice cleaning, airflow velocity, airflow inclined angle, experiment

Binelo M O, de Lima R F. Modelling of the drag force of agricultural seeds applied to the discrete element method. Biosystems Engineering, 2019; 178: 168–175.

Du X Q, Xiao M H, Hu X Q, Chen J N, Zhao Y. Numerical simulation and experiment of gas-solid two-phase flow in cross-flow rice cleaning device. Transactions of the CSAE, 2014; 30(3): 27–34. (in Chinese)

Fu J, Chen Z, Han L J, Ren L Q. Review of rice threshing theory and technology. Int J Agric & Biol Eng, 2018, 11(3): 12–20.

Katterfeld A, Wensrich C. Understanding granular media: From fundamentals and simulations to industrial application. Granular Matter, 2018, 19(4): 83. doi: 10.1007/s10035-017-0765-y.

Huang Y X, Wang B T, Yao Y X, Ding S P, Zhang J C, Zhu R X. Parameter optimization of fluted-roller meter using discrete element method. Int J Agric & Biol Eng, 2018; 11(6): 65–72.

Ucgul M, Fielke J M, Saunders C. Three-dimensional discrete element modelling (DEM) of tillage: Accounting for soil cohesion and adhesion. Biosystems Engineering, 2014; 129: 298–306.

Hu J, Fan G. CFD simulation of heating process of greenhouse irrigation water in wintering period. Applied Engineering in Agriculture, 2017; 33(4): 575–586.

Han D D, Zhang D X, Jing H R, Yang L, Cui T, Ding Y Q, et al. DEM-CFD coupling simulation and optimization of an inside-filling air-blowing maize precision seed-metering device. Computers and Electronics in Agriculture, 2018; 150: 426–438.

He Y, Bayly A E, Hassanpour A. Coupling CFD-DEM with dynamic meshing: A new approach for fluid-structure interaction in particle-fluid

flows. Powder Technology, 2018; 325: 620–631.

Ren B, Zhong W Q, Chen Y, Chen X, Jin B S, Yuan Z L, et al. CFD-DEM simulation of spouting of corn-shaped particles. Particulogy, 2012; 10(5): 562–572.

Yuan J B, Wu C Y, Li H, Qi X D, Xiao X X, Shi X X. Movement rules and screening characteristics of rice-threshed mixture separation through a cylinder sieve. Computers and Electronics in Agriculture, 2018; 154: 320–329.

Dai F, Song X F, Zhao W Y, Han Z S, Zhang F W, Zhang, S L. Motion simulation and test on threshed grains in tapered threshing and transmission device for plot wheat breeding based on CFD-DEM. Int J Agric & Biol Eng, 2019; 12(1): 65–72.

Mahmudah R S N, Kumabe M, Suzuki T, Guo L, Morita K. 3D Simulation of solid-melt mixture flow with melt solidification using a finite volume particle method. Journal of Nuclear Science and Technology, 2011; 48(10): 1300–1312.

Sturm M, Wirtz S, Scherer V, Denecke J. Coupled DEM-CFD simulation of pneumatically conveyed granular media. Chemical Engineering & Technology, 2010; 33(7): 1184–1192.

Lei X L, Liao Y T, Liao Q X. Simulation of seed motion in seed feeding device with DEM-CFD coupling approach for rapeseed and wheat. Computers and Electronics in Agriculture, 2016; 131: 29–39.

Zhou L, Zhang L J, Bai L, Shi W D, Li W, Wang C, Agarwal R. Experimental study and transient CFD/DEM simulation in a fluidized bed based on different drag models. RSC Advances, 2017; 7(21): 12764–12774.

Adema A T, Yang Y X, Boom R. Discrete Element Method-Computational fluid dynamic simulation of the materials flow in an Iron-making blast furnace. ISIJ International, 2010; 50(7): 954–961.

Wiacek J. Geometrical parameters of binary granular mixtures with size ratio and volume fraction: experiments and DEM simulations. Granular Matter, 2016; 18(3): 42. doi: 10.1007/s 10035-016-0642-0

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; 16(6): 231–239.

Ma X D, Zhang Y B, Liu Y, Zheng X W. Simulation of grain segregation under horizontal rotational oscillations. Granular Matter, 2016; 18(1): 8. doi: 10.1007/s10035-015-0598-5.

Alberto D R, Francesco P D M. Comparison of contact-force models for the simulation of collisions in DEM-based granular flow codes. Chemical Engineering Science, 2004; 59(3): 525–541.

Langston P A, Tuzun U, Heyes D M. Discrete element simulation of granular flow in 2D and 3D hoppers: Dependence of discharge rate and wall stress on particle interactions. Chemical Engineering Science, 1996; 50(6): 967–987.

Zhou Y C, Wright R Y, Yang B H, Xu A B. Rolling friction in the dynamic simulation of sandpile formation. Physica A, 1999; 269(2): 536–553.

Zhou Y, Wang H B, Zhou B, Li J. DEM-aided direct shear testing of granular sands incorporating realistic particle shape. Granular Matter, 2018; 20(3): 55. doi: 10.1007/s10035-018-0828-8.

Markauskas D, Kacianauskas R. Investigation of rice flow by multi-sphere particle model with rolling resistance. Granular Matter, 2011; 13(2), 143–148.

Liang Z W, Li Y M, Xu LZ, Zhao Z. Sensor for monitoring rice sieve losses in combine harvesters. Biosystems Engineering, 2016; 147: 51–66.

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.