In order to further clarify and improve the working performance of separating cleaning device of flax threshing material, and study the motion law and characteristics of components of flax threshing material, in this paper, numerical simulation was carried out on the separating cleaning process of flax threshing material based on CFD-DEM method. Simulation results showed that the components of flax threshing material were separated and cleaned under the influence of airflow field, meanwhile, variation curves of quantity and mean velocity of flax seeds in the separating cleaning system were obtained. By referring to streamline distribution of gas-solid coupling, the quantity variation law of components of flax threshing material with time was explored and their motion curves and variation tendency of average velocity were studied. Verification test results showed that the cleaning rate of separating cleaning device for flax threshing material was 92.66% with 1.58% of total separation loss. Compared with simulation results, the test results were 1.34% and 0.93% lower, showing that it is feasible to apply the gas-solid coupling theory and method to simulate the separating and cleaning operation of flax threshing material.
Keywords: flax threshing material, separating cleaning device, hydromechanics calculation, discrete element, numerical simulation, test
DOI: 10.25165/j.ijabe.20201301.5196

Citation: Dai F, Song X F, Guo W J, Zhao W Y, Zhang F W, Zhang S L. Simulation and test on separating cleaning process of flax threshing material based on gas-solid coupling theory. Int J Agric & Biol Eng, 2020; 13(1): 73–81.

flax threshing material, separating cleaning device, hydromechanics calculation, discrete element, numerical simulation, test

Wang L M, Zhang J P, Dang Z, Pei X W, Dang Z H. The analysis of the parental combining ability and heterosis on two-line hybrid flax. Scientia Agricultura Sinica, 2016; 49(6): 1047–1059. (in Chinese)

Dujardin N, Fois M, Grimau M, Poilane C. Soft interface dynamics in flax-fabrics/epoxy composites. Composite Structures, 2018; 202: 389–396.

Liao Q X, Chen L, Li H T, Han C R, Liu M F. Cleaning unit test-bed of extraction components for rape combine harvester. Transactions of the Chinese Society for Agricultural Machinery, 2013; 44(10): 80–85, 79. (in Chinese)

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

Jerzy M, Wojciech M, Grzegorz S, Jacek K, Andrzej K, Damian K, Krzysztof P. Research on new technology of fiber flax harvesting. Journal of Natural Fibers, 2018; 15(1): 53–61.

Jin X, Zhao K X, Ji J T, Du X W, Ma H, Qiu Z M. Design and implementation of intelligent transplanting system based on photoelectric sensor and PLC. Future Generation Computer Systems, 2018; 88(1): 127–139.

Kuang S B, Yu A B, Zou Z S. Computational study of flow regimes in vertical pneumatic conveying. Industrial & Engineering Chemistry Research, 2009; 48(14): 6846–6858.

Peng Z B, Doroodchi E, Moghtaderi B, Evans G M. A DEM-based

analysis of the influence of aggregate structure on suspension shear yield stress. Advanced Powder Technology, 2012; 23(4): 437–444.

Li H C, Li Y M, Gao F, Zhao Z, Xu Li Z. CFD-DEM simulation of material motion in air-and-screen cleaning device. Computers and Electronics in Agriculture, 2012; 88(6): 111–119.

Zhao Z, Li Y M, Liang Z W, Gong Z Q. DEM simulation and physical testing of rice seed impact against a grain loss sensor. Biosystems Engineering, 2013; 116: 410–419.

Liu H X, Guo L F, Fu L L, Tang S F. Study on multi-size seed-metering device for vertical plate soybean precision planter. Int J Agric & Biol Eng, 2015; 8(1): 1–8.

He Y, Bayly A E, Hassanpour A L. Coupling CFD-DEM with dynamic meshing: A new approach forfluid-structure interaction in particle-fluid flows. Powder Technology, 2018; 325: 620–631.

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): 66–73.

Jiang E C, Sun Z F, Pan Z Y, Wang L J. Numerical simulation based on CFD-DEM and experiment of grain moving laws in inertia separation chamber. Transactions of the CSAM, 2014; 45(4): 117–122. (in Chinese)

Liu L Y, Hao S Y, Zhang M, Liu D M, Jia F G, Quan L Z. Numerical simulation and experiment on paddy ventilation resistance based on CFD-DEM. Transactions of the CSAM, 2015; 46(8): 27–32. (in Chinese)

Boac J M, Ambrose R P K, Casada M E, Maghirang R G, Maier D E. Applications of discrete element method in modeling of grain postharvest

operations. Food Engineering Reviews, 2014; 6(4): 128–149.

Oldal I, Safranyik F. Extension of silo discharge model based on discrete element method. Journal of Mechanical Science & Technology, 2015; 29(9): 3789–3796.

Dai F, Zhao W Y, Liu G C, Zhang S L, Shi R J, Wei B. Design and experiment of separating and cleaning machine for flax threshing material. Transactions of the CSAM, 2019; 50(8): 140–147. (in Chinese)

Wang J W, Zhou W Q, Tian L Q, Li S W, Zhang Z. Virtual simulation analysis and verification of seed-filling mechanism for dipper hill-drop precision direct rice seeder. Int J Agric & Biol Eng, 2017; 10(6): 77–85.

Ma L C, Wei L B, Pei X Y, Zhu X S, Xu D R. CFD-DEM simulations of particle separation characteristic in centrifugal compounding force field. Powder Technology, 2019; 343: 11–18.

Wang S Y, Li H L, Wang R C, Wang X, Tian R C, Sun Q J. Effect of the inlet angle on the performance of a cyclone separator using CFD-DEM. Advanced Powder Technology, 2019; 30(2): 227–239.

Bart L, Bart M, Josse D B, Wouter S, LiDaR sensing to monitor straw output quality of a combine harvester. Computers and Electronics in Agriculture, 2012; 85(1): 40–44.

Tang Z, Li Y M, Xu L Z, Francis K. Modeling and design of a combined transverse and axial flow threshing unit for rice harvesters. Spanish Journal of Agricultural Research, 2014; 12(4): 973–983.

Jiří S, Tomáš S, Jan M. Analysis of linseed production with use of flax puller and combine harvester for its harvest. Acta Universitatis Agriculturae et Silviculturae Mendelianae Brunensis, 2017; 65(2): 511–517.