According to the agronomic requirements of orchard planting pattern and fertilization in Xinjiang, the soil particle models and a soil-trenching device interaction model were established by using discrete element simulation software in order to find out the law of influence of structure parameters and working parameters on the operation power consumption of a segmented cutting trenching device; moreover, its cutting process was simulated according to the response surface test design. According to the results of research on the influence of forward speed, cutter disk speed and cutter disk combination on the operation power consumption of the segmented cutting trenching device, the law of their influence on the operation power consumption in descending order is forward speed, cutter disk combination, cutter disk speed. According to the response surface test result, the following influential factor parameter combination has been obtained: forward speed 815 m/h, cutter disk speed 112 r/min, cutter disk combination A (cut angle 150°, bent angle 60° and working width 133 mm), cutter disk combination B (cut angle 180°, bent angle 90° and working width 166 mm), and trenching operation power consumption-optimization results were verified through field tests. According to the verification, the results showed a high accuracy of the simulation, with a relative error mean of 3.18% between the theoretical value and the field test value. This study can provide a reference for the energy-saving design of orchard trenching devices.
Keywords: trenching device, discrete element, orchard, power consumption, simulation analysis, parameter optimization
DOI: 10.25165/j.ijabe.20211401.5477

Citation: Ma C, Qi J T, Kan Z, Chen S J, Meng H W. Operation power consumption and verification tests of a trenching device for orchards in Xinjiang based on discrete element. Int J Agric & Biol Eng, 2021; 14(1): 133–141.

trenching device, discrete element, orchard, power consumption, simulation analysis, parameter optimization

National Bureau of Statistics of the People's Republic of China. China Statistical Yearbook. Beijing: China Statistics Press, 2020; pp.370–373. (in Chinese)

Jiang N. Orchard full mechanization equipment. Contemporary Farm Machinery, 2019; 10: 59. (in Chinese)

Zhang F. Do a good job in agricultural non-point source pollution prevention and control battle "one control, two reductions and three basics" goal refers to agricultural resources. China Agricultural Materials, 2015; 14: 3. (in Chinese)

Asl J H, Singh S. Optimization and evaluation of rotary tiller blades: Computer solution of mathematical relations. Soil & Tillage Research, 2009; 106(1): 1–7.

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.

UMootaz, H R, Boyle J T. 3D dynamic analysis of soil-tool interaction using the finite element method. Journal of Terramechanics, 2003; 40(1): 51–62.

Zhu J H, Li Z G, Zou J. The CAD system for rotary tiller blade design. Transactions of the CSAM, 1985; 26(3): 51–61. (in Chinese)

Zhu X M. Research on power consumption of rotary tiller. Journal of Anhui Institute of Technology, 1986; 5(3): 121–133. (in Chinese)

Zhu X M. Discuss with Zhu Jinhua and other comrades about CAD system of rotary tiller blade design. Journal of Agricultural Machinery, 1986; 4: 78–86. (in Chinese)

Qin G L, Liao Q X, Zhou S X. Optimization design and analysis of power consumption of chain ditching machine based on MATLAB. Hubei Agricultural Sciences, 2009; 48(1): 210–214. (in Chinese)

Zhang Q, Wang W, Liao J A. Design of fertilizing machine’s furrow opener in jujube orchard and finite element analysis. Journal of Agricultural Mechanization Research, 2016; 38(4): 23–28. (in Chinese)

Kang J M, Li S J, Yang X J, Liu L J, Li C R. Simulation analysis and experimental verification of power consumption of disc ditcher. Transactions of the CSAE, 2016; 32(13): 8–15. (in Chinese)

Pan S Q. Optimal design and experimental research of core-shaft opener based on discrete element method. PhD dissertation. Changchun: Jilin University, 2015; 92p. (in Chinese)

Tian D Y, Liu J D, Jiao H B. Optimization and analysis of working parameters of soil covering disc based on discrete element method. Journal of Agricultural Mechanization Research, 2018; 40(9): 16–22, 59. (in Chinese)

Jia H L, Wang Q, Huang D Y. Design of bionic mole forelimb intelligent row cleaners. Int J Agric & Biol Eng, 2019; 12(3): 27–35.

Lin J, Zhang T J, Tian Y, Gao W Y, Qi L, Li B F. Optimization and experiment of biomimetic trenching device for returning straw in field. Transactions of the CSAM, 2018; 49(S1): 50–59, 67. (in Chinese)

Bernacki H. Theory of rotary cultivators. Warsaw Institute of mechatronics. Research brief, N2, Warsaw, 1962; 2(1): 9–61.

Department of Theoretical Mechanics, Harbin Institute of Technology. Theoretical mechanics. Higher Education Press, 2009; 389p. (in Chinese)

Li J Q. Rotary ditching machine. Beijing: China Agricultural Machinery Press, 1984;236p. (in Chinese)

Li Y J, Wu T, Lin J H, Xu Y. Analysis of the motion characteristics of sand particles by the penetration cone based on discrete element method. Transactions of the CSAE, 2012; 28(24): 55–61.(in Chinese)

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: 298–306.

Ma Y J, Wang A, Zhao J G. Simulation analysis and experiment on drag reduction effect of convex blade subsoiler based on discrete element method. Journal of Agricultural Engineering, 2019; 35(3): 16-23. (in Chinese)

Tamás K, Jóri I J, Mouazen A M. Modelling soil–sweep interaction with discrete element method. Soil & Tillage Research, 2013; 134(8): 223–231.

Braja M D. Advanced soil mechanics. Taylor & Francis, 2008; 600p.

Fielke J M. Interactions of the cutting edge of tillage implements with soil. Journal of Agricultural Engineering Research, 1996; 63(1): 61–71.

Li Y Y, Hu C R. Experimental design and data processing. Beijing: Chemical Industry Press, 2008; 257p. (in Chinese)

Ren L Q. Experimental design and optimization. Beijing: Science Press, 2009; 259p. (in Chinese)