Calibration of the simulation parameters of the particulate materials in film mixed materials
Keywords:
cotton field, agricultural film, particulate material, EDEM, contact parameter, response model, calibrationAbstract
In order to obtain accurate contact parameters of a particulate material in residual film mixture collected by cotton field machine in Xinjiang, the angle of repose test and inclined plane test were carried out. In the tests, the angles of repose of the particulate material with the water content of (6.26±1.5)% and (14.1±2.1)% were measured respectively, as well as the static sliding friction angle between the particulate material and the residual film. At the same time, the EDEM software was used to calibrate the coefficient of restitution, static friction coefficient and dynamic friction coefficient between the material and the film. Then, the second-order response model between contact parameters and the angle of repose and static sliding friction angle was constructed. In addition, the optimal contact parameters between the granular materials and the mulch were obtained by fitting the physical test data. The results indicated that the errors between the physical test results and the numerical simulation results are small. It was proved that the second-order response model could predict the repose angle of granular materials and the static sliding friction angle between granular materials and farmland film. This study could provide theoretical support for the subsequent model construction of the residual film mixture collected by the cotton field machine. Keywords: cotton field, agricultural film, particulate material, EDEM, contact parameter, response model, calibration DOI: 10.25165/j.ijabe.20201304.5586 Citation: Liang R Q, Chen X G, Jiang P, Zhang B C, Meng H W, Peng X B, et al. Calibration of the simulation parameters of the particulate materials in film mixed materials. Int J Agric & Biol Eng, 2020; 13(4): 29–36.References
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[2] Liu F Y, Zhang J, Li B, Chen J. Calibration of parameters of wheat required in discrete element method simulation based on repose angle of particle heap. Transactions of the CSAE, 2016; 32(12): 247–253. (in Chinese)
[3] C González-Montellano, Fuentes J M, E Ayuga-Téllez, Ayuga, F. Determination of the mechanical properties of maize grains and olives required for use in DEM simulations. Journal of Food Engineering, 2012; 111(4): 553–562.
[4] Rackl M, Hanley K J. A methodical calibration procedure for discrete element models. Powder Technology, 2017; 307: 73–83.
[5] Yuan Q C, Xu L M, Xing J J, Duan Z Z, Ma S, Yu C C, et al. Parameter calibration of discrete element model of organic fertilizer particles for mechanical fertilization. Transactions of the CSAE, 2018; 34(18): 21–27. (in Chinese)
[6] Zeng Z W, Chen Y, Zhang X. Modelling the interaction of a deep tillage tool with heterogeneous soil. Computers and Electronics in Agriculture, 2017; 143(12): 130–138.
[7] Beakawi Al-Hashemi H M, Baghabra Al-Amoudi O S. A review on the angle of repose of granular materials. Powder Technology, 2018; 330: 397–417.
[8] Behjani M A, Rahmanian N, Nur F B A G, Hassanpour A. An investigation on process of seeded granulation in a continuous drum granulator using dem. Advanced Powder Technology, 2017; 28(10): 2456–2464.
[9] E Silva B B, Da Cunha E R, De Carvalho R M, Tavares Luís Marcelo. Modeling and simulation of green iron ore pellet classification in a single deck roller screen using the discrete element method. Powder Technology, 2018; 332(6): 359–370.
[10] Persson A S, Alderborn G, Frenning G. Flowability of surface modified pharmaceutical granules: A comparative experimental and numerical study. European Journal of Pharmaceutical Sciences, 2011; 42(3): 199–209.
[11] Guo Z G, Chen X L, Liu H F, Guo Q, Guo X L, Lu H F. Theoretical and experimental investigation on angle of repose of biomass–coal blends. Fuel, 2014; 116(1): 131–139.
[12] Roessler T, Katterfeld A. Dem parameter calibration of cohesive bulk materials using a simple angle of repose test. Particuology, 2019; 45(1): 105–115.
[13] Cheng N S, Zhao K. Difference between static and dynamic angle of repose of uniform sediment grains. International Journal of Sediment Research, 2017; 32(2): 149–154.
[14] Lin J C, Luo S, Yuan Q X, Cao H L. Flow properties of vermicompost particle with different moisture contents. Transactions of the CSAE, 2019; 35(9): 221–227. (in Chinese)
[15] Li B, Chen Y, Chen J. Modeling of soil-claw interaction using the discrete element method (DEM). Soil and Tillage Research, 2016; 158(5): 177–185.
[16] Zeng Z W, Chen Y. Simulation of straw movement by discrete element modelling of straw-sweep-soil interaction. Biosystems Engineering, 2019; 180: 25–35.
[17] Ucgul M, Fielke J M, Saunders C. Three-dimensional discrete element modelling of tillage: Determination of a suitable contact model and parameters for a cohesionless soil. Biosystems Engineering, 2014; 121(2): 105–117.
[18] Ucgul M, Fielke J M, Saunders C. Three-dimensional discrete element modelling (DEM) of tillage: Accounting for soil cohesion and adhesion. Biosystems Engineering, 2015; 129(1): 298–306.
[19] Ucgul M, Saunders C, Fielke J M. Discrete element modelling of top soil burial using a full scale mouldboard plough under field conditions. Biosystems Engineering, 2017; 160(8): 140–153.
[20] Li J W, Tong J, Hu B, Wang H B, Mao C Y, Ma Y H. Calibration of parameters of interaction between clayey black soil with different moisture content and soil-engaging component in northeast China. Transactions of the CSAE, 2019; 35(6): 130–140. (in Chinese)
[21] Wu T, Huang W F, Chen X S, Ma X, Han Z Q, Pan T. Calibration of discrete element model parameters for cohesive soil considering the cohesion between particles. Journal of South China Agricultural University, 2017; 38(3): 93–98. (in Chinese)
[22] He Y M, Xiang W, Wu M L, Quan W, Chen C P. Parameters calibration of loam soil for discrete element simulation based on the repose angle of particle heap. Journal of Hunan Agricultural University (Natural Sciences), 2018; 44(2): 216–220. (in Chinese)
[23] Xiang W, Wu M l, Lü J N, Quan W, Ma L, Liu J J. Calibration of simulation physical parameters of clay loam based on soil accumulation test. Transactions of the CSAE, 2019; 35(12): 116–123. (in Chinese)
[24] Wang X L, Hu H, Wang Q J, Li H W, He J, Chen W Z. Calibration method of soil contact characteristic parameters based on DEM theory. Transactions of the CSAM, 2017; 48(12): 78–85. (in Chinese)
[25] Shi L R, Zhao W Y, Sun W. Parameter calibration of soil particles contact model of farmland soil in northwest arid region based on discrete element method. Transactions of the CSAE, 2017; 33(21): 181–187. (in Chinese)
[26] Dai F, Song X F, Zhao W Y, Zhang F W, Ma H J, Ma M Y. Simulative calibration on contact parameters of discrete elements for covering soil on whole plastic film mulching on double ridges. Transactions of the CSAM, 2019; 50(2): 49–56+77. (in Chinese)
[27] Zhang R, Han D L, Ji Q L, He Y, Li J Q. Calibration methods of sandy soil parameters in simulation of discrete element method. Transactions of the CSAM, 2017; 48(3): 49–56. (in Chinese)
[28] Tanaka H, Momozu M, Oida A. Simulation of soil deformation and resistance at bar penetration by the Distinct Element Method. Journal of Terramechanics, 2000; 37(1): 41–56.
[29] Jin F, Xin H L, Zhang C H, Sun Q C. Probability-based contact algorithm for non-spherical particles in DEM. Powder Technology, 2011; 212(1): 134–144.
[30] Zheng K, He J, Li H W, Diao P S, Wang Q J, Zhao H B. Research on polyline soil-breaking blade subsoiler based on subsoiling soil model using discrete element method. Transactions of the CSAM, 2016; 47(9): 62–72. (in Chinese)
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Published
2020-08-07
How to Cite
Liang, R., Chen, X., Jiang, P., Zhang, B., Meng, H., Peng, X., & Kan, Z. (2020). Calibration of the simulation parameters of the particulate materials in film mixed materials. International Journal of Agricultural and Biological Engineering, 13(4), 29–36. Retrieved from https://ijabe.migration.pkpps03.publicknowledgeproject.org/index.php/ijabe/article/view/5586
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Applied Science, Engineering and Technology
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