Existing discrete element method-based simulation analysis of Panax notoginseng root soil separation still has the challenge to get the accurate and reliable basic parameters, which are necessary for discrete element simulation. In this paper, the P. notoginseng roots suitable for harvesting period were taken as the experimental object. Then using 3D scanning reverse modeling technology and EDEM software to establish the discrete element model of P. notoginseng, based on which, the physical and virtual tests were carried out to calibrate the simulation parameters. First, the basic physical parameters (density, triaxial geometric size, moisture content, shear modulus, and elastic modulus) and contact coefficients (static friction coefficient, rolling friction coefficient, and crash recovery coefficient between P. notoginseng roots and 65Mn steel) were measured by physical tests. Furthermore, treating the contact coefficients of P. notoginseng roots as the influence factor, the steepest uphill test, and four factors combing five levels of rotational virtual simulation are conducted. The measured relative error accumulation angle and simulation accumulation angle are set as the performance indices. The results show that the static friction coefficient, rolling friction coefficient, crash recovery coefficient, and surface energy coefficient of P. notoginseng roots are 0.55, 0.35, 0.16, and 19.5 J/m2, respectively. Using calibration results as parameters of the vibration separation simulation test of P. notoginseng soil, the Box-Behnken vibration separation simulation tests were carried out, in which the vibration frequency, inclination angle, and vibration amplitude of separation device as factors, screening rate and damage rate of P. notoginseng soil complex are regarded as indices. The results show that the optimal operating parameters of the separation device are the vibration frequency of 10 Hz, the inclination angle of 5°, and the amplitude of 6 cm. Based on the optimal operation parameters, the discrete element simulation experiment and field experiment of P. notoginseng roots soil separation are also performed to compare the soil three-dimensional trajectory space coordinates of P. notoginseng roots. From the results, three axis coordinate error is less than 15%. This proves that the calibration results are reliable. It can also provide the theoretical basis and technical support for the further study of the P. notoginseng root soil separation platform.
Key words: Panax notoginseng; root; EDEM; parameter calibration; separation test
DOI: 10.25165/j.ijabe.20241704.8122

Citation: Xie K T, Zhang Z G, Wang F A, Yu X L, Wang C L, Jiang S F. Calibration and experimental verification of discreteelement parameters of Panax notoginseng root. Int J Agric & Biol Eng, 2024; 17(4): 13–23.

Panax notoginseng; root; EDEM; parameter calibration; separation test

Li J B, Bao Y L, Wang Z, Yang Q, Cui X M. Research progress in diseases of Panax notoginseng. Physiological and Molecular Plant Pathology, 2022; 121: 101878.

Coetzee C J. Review calibration of the discrete element method. Power Technology, 2017; 310: 104–142.

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

Turkia S B, Wilke D N, Pizette P, Govender N, Abriak N E. Benefts of virtual calibration for discrete element parameter. Granular Matter, 2019; 21(110): 1–16.

Yang Q Z, Shi L, Shi A P, He M S, Zhao X Q, Zhang L, Addy M. Determination of key soil characteristic parameters using angle of repose and direct shear stress test. Int J Agric & Biol Eng, 2023; 16(3): 143-150.

Zhang Z G, Zeng C, Xing Z Y, Xu P, Guo Q F, Shi R M, Wang Y Z. Discrete element modeling and parameter calibration of safflower biomechanical properties. Int J Agric & Biol Eng, 2024; 17(2): 37–46.

Yu Y, Diao L S, Wang D W, Wang J S, Wang X M, Tan X Z, Yi D Z. Lightweight design of peanut sowing machine frame based on finite element analysis. Int J Agric & Biol Eng, 2023; 16(3): 120–129.

Li Y X, Li F X, Xu X M, Shen C P, Meng K P, Chang D T. Parameter calibration of wheat flour for discrete element method simulation based on particle scaling. Transactions of the CSAE, 2019; 35(16): 320–327. (in Chinese)

Khatchatourian O A, Binelo M O, de Lima R F. Simulation of soya beanflow in mixed-flow dryersusing DEM. Biosystems Engineering, 2014; 123: 68–76.

Peng C W, Chen J W, He X, Sun S L, Yin Y L, Chen Z. Discrete element modeling and verification of the simulation parameters for chopped hybrid Broussonetia papyrifera stems. Int J Agric & Biol Eng, 2024; 17(1): 23–32.

Hao J J, Wei W B, Huang P C, Qin J H, Zhao J G. Calibration and experimental verification of discrete element parameters of oil sunflower seeds. Transactions of the CSAE, 2021; 37(12): 36–44. (in Chinese)

Hou Z F, Dai N Z, Chen Z, Chou Y, Zhang X W. Measurement and calibration of physical property parameters for Agropyron seeds in a discrete element simulation. Transactions of the CSAE, 2020; 36(24): 46–54. (in Chinese)

Liu F Y, Zhang J, Chen J. Construction of visco-elasto-plasticity contact model of vibratory screening and its parameters calibration for wheat. Transactions of the CSAE, 2018; 34(15): 37–43. (in Chinese)

Bai S H, Yuan Y W, Niu K, Zhou L M, Zhao B, Liu L J, et al. Simulation parameter calibration and experimental study of a discrete element model of cotton precision seed metering. Agriculture, 2022; 12(870): 1–20.

Zhang G Z, Chen L M, Liu H P, Dong Z, Zhang Q H, Zhou Y. Calibration and experiments of the discrete element simulation parameters for water chestnut. Transactions of the CSAE, 2022; 38(11): 41–50. (in Chinese)

Shu C X, Yang J, Wan X Y, Yuan J C, Liao Y T, Liao Q X. Calibration and experiment of the discrete element simulation parameters of rape threshing mixture in combine harvester. Transactions of the CSAE, 2022; 38(9): 34–43. (in Chinese)

Ma Y H, Song C D, Xuan C Z, Wang H Y, Yang S, Wu P. Parameters calibration of discrete element model for alfalfa straw compression simulation. Transactions of the CSAE, 2020; 36(11): 22–30. (in Chinese)

Liu F Y, Zhang J, Chen J. Modeling of flexible wheat straw by discrete element method and its parameters calibration. Int J Agric & Biol Eng, 2018; 11(3): 42–46.

Wu M C, Cong J L, Yan Q, Zhu T, Peng X Y, Wang Y S. Calibration and experiments for discrete element simulation parameters of peanut seed particles. Transactions of the CSAE, 2020; 36(23): 30–38. (in Chinese)

Shi L R, Ma Z T, Zhao Wuyun, Yang X P, Sun B G, Zhang J P. Calibration of simulation parameters of flaxed seeds using discrete element method and verification of seed-metering test. Transactions of the CSAE, 2019; 35(20): 25–33. (in Chinese)

Shi L R, Yang X P, Zhao W Y, Sun W, Wang G P, Sun B G. Investigation of interaction effect between static and rolling friction of corn kernels on repose formation by DEM. Int J Agric & Biol Eng, 2021; 14(5): 238–246.

Fan G J, Wang S Y, Shi W J, Gong Z F, Gao M. Simulation parameter calibration and test of typical pear varieties based on discrete element method. Agronomy, 2022; 12(1720): 1–18.

Song S L, Tang Z H, Zheng X, Liu J B, Meng X J, Liang Y C. Calibration of the discrete element parameters for the soil model of cotton field after plowing in Xinjiang of China. Transactions of the CSAE, 2021; 37(20): 63–70. (in Chinese)

Xing J J, Zhang R, Wu Pg, Zhang X R, Dong X H, Chen Y, Ru S F. Parameter calibration of discrete element simulation model for latosol particles in hot areas of Hainan Province. Transactions of the CSAE, 2020; 36(5): 158–166. (in Chinese)

Peng C W, Xu D J, He X, Tang Y H, Sun S L. Parameter calibration of discrete element simulation model for pig manure organic fertilizer treated with Hermetia illucen. Transactions of the CSAE, 2020; 36(17): 212–218. (in Chinese)

Yuan Q C, Xu L M, Xing J J, Duan Z Z, Ma S, Yu C C, Chen C. Parameter calibration of discrete element model of organic fertilizer particles for mechanical fertilization. Transactions of the CSAE, 2018; 34(18): 21–27. (in Chinese)

Xie F P, Wu Z Y, Wang X S, Liu D W, Wu B, Zhang Z Z. Calibration of discrete element parameters of soils based on unconfined compressive strength test. Transactions of the CSAE, 2020; 36(13): 39–47. (in Chinese)

Yan D X, Yu J Q, Wang Y, Zhou L, Tian Y, Zhang. Soil particle modeling and parameter calibration based on discrete element method. Agriculture, 2022; 12(1421): 1–15.

Ma S, Xu L M, Yuan Q C, Niu C, Zeng J, Chen C, Wang S S, Yuan X T. Calibration of discrete element simulation parameters of grapevine antifreezing soil and its interaction with soil-cleaning components. Transactions of the CSAE, 2020; 36(1): 40–49. (in Chinese)

GB/T 1933-2009, Method for determination of the density of wood. Chian: General Administration of Quality Supervision, Inspection and Quarantine of the People’s Republic of China, 2009. (in Chinese)

GB/T 1931-2009, Method for determination of the moisture content of wood. Chian: General Administration of Quality Supervision, Inspection and Quarantine of the People’s Republic of China, 2009. (in Chinese)

Zhao F F. The tractive notoginseng harvester design and experimental research . Kunming: Kunming University of Science and Technology, 2016; 11–22. (in Chinese)

Xie K T, Zhang Z G, Wang Y C, Tang J X, Yu X L. Simulation analysis and test of Panax notoginseng excavating shovel based on LS-DYNA. Journal of Northeast Agricultural University, 2021; 52(5): 79–88. (in Chinese)

Zhang S W, Zhang R Y, Chen T Y, Fu J, Yuan H F. Calibration of simulation parameters of mung bean seeds using discrete element method and verification of seed-metering test. Transactions of the CSAM, 2022; 53(3): 71–79.

JB/T 9014.7-1999, Determination of accumulated angle. China, Machinery Industry Standard, 2000. (in Chinese)

Müller D, Fimbinger E, Brand C. Algorithm for the determination of the angle of repose in bulk material analysis. Powder Technology, 2021; 383: 598–605.

Wang Y C. Study on mining mechanism of Panax notoginseng based on discrete element method . Kunming: Kunming University of Science and Technology, 2021; 11–33. (in Chinese)