Aiming to solve problems in organic rice weeding a type of post-seat weeding machine was designed for rice paddies. The differences in the strengths and lengths of the root systems between the rice seedlings and the weeds were studied, and the motion track of the weeding wheel was analyzed to obtain the structural parameters of the weeding wheel. Then, the structural model of the weeding wheel was designed. The interaction process between the weeding wheel and soil in the paddy fields was simulated and analyzed based on the discrete element method, so as to investigate the working resistance change tendency of the weeding wheel and the orderliness of the soil disturbances. An orthogonal test was designed in this study, with three factors: the hoeing depth, the rotation rate of the weeding wheel, and the forward speed of the device. The influences of different operation parameters of the weeding machine on the weeding torque and soil disturbance speed were obtained based on a variance analysis of the test results. A multi-index comprehensive weighted scoring method was used to evaluate the simulation results. A soil bin test was conducted to verify the simulation results. Field experiments were carried out to test the working performance of the weeding machine. The comprehensive scoring results indicated that a better working performance of the weeding operation could be obtained when the hoeing depth was 50 mm, the rotation rate of the weeding wheel was 240 r/min, and the forward speed was 0.6 m/s. The results of the soil bin test were consistent with the simulation results. The results of the field experiment revealed that the weeding machine met the requirements for organic rice weeding. These results can provide a reference for the design of weeding machines for paddy fields.
Keywords: paddy field, weeding, structural parameters, discrete element method, soil
DOI: 10.25165/j.ijabe.20211403.5936

Citation: Tian L, Cao C M, Qin K, Fang L F, Ge J. Design and test of post-seat weeding machine for paddy. Int J Agric & Biol Eng, 2021; 14(3): 112–122.

paddy field, weeding, structural parameters, discrete element method, soil

Bond W, Grundy A C. Non-chemical weed management in organic farming system. Weed Research, 2001; 41(5): 383–405.

Chen Z W, Zhang C L, Li N, Sun Z. Study review and analysis of high performance intra-row weeding robot. Transactions of the CSAE, 2015; 31(5): 1–8. (in Chinese)

Wang J F, Wang J W, Yan D W, Zhou W. Design and experiment of 3SCJ-2 type row weeding machine for paddy field. Transactions of the CSAM, 2017; 48(6): 71–78, 202.

Usui T, Ito K, Osato T. Weeding effect of fixed tine type weeding machine in rice cultivation. Tohoku Weed Research Society, 2009; 9: 38–41.

Minoru Sangyo Co., Ltd. Weeding machine. Japan; 4038538, 2007-11-16.

Wado Sangyo Co., Ltd. Paddy weeding machine. Japan; 4057492, 2007-12-21.

Ishii H, Sato M. Measures to improve the performance of weeding machines for paddy field tillage and to improve the weeding effect. Bulletin of the Kanto Branch of the Crop Science Society of Japan, 2006; (21): 22–23.

Agriculture and Food Technology Research Institute, Kubota Corporation, Iseki Agricultural Machinery Co., Ltd. Paddy weeding machine. Japan; 3965430, 2007-06-08.

Qi L, Ma X, Tan Z T, Tan Y. Development and experiment of marching-type inter-cultivation weeding machine for paddy. Transactions of the CSAE, 2012; 28(14): 31–35. (in Chinese)

Wang J W, Li C, Li X. Design and experiment of 3scj-1 type weeding machine for paddy field applied to film mulching and transplanting. Transaction of the CSAM, 2018; 49(4): 102–109. (in Chinese)

Qi L, Zhao L L, Ma X, Cui H, Zheng W, Lu Y. Design and test of 3gy-1920 wide-swath type weeding-cultivating machine for paddy. Transactions of the CSAE, 2017; 33(8): 47–55. (in Chinese)

Qi L, Liang Z W, Jiang Y, Ma X, Wu T, Lu Y L, et al. Design and field test of lightweight paddy weeding machine. Journal of Jilin University (Engineering and Technology Edition), 2016; 46(3): 1004–1012. (in Chinese)

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

Cundall P A, Strack O D L. A DISCRETE NUMERICAL MODE FOR GRANULAR ASSEMBlies. Géotechnique, 1979; 29(1): 47–65.

Shmulevich I, Horn R. State of the art modeling of soil-tillage interaction using discrete element method. Soil Tillage Research, 2010; 111(1): 41–53.

Ucgul M, Fielke J M, Saunders C. 3D DEM tillage simulation: validation of a hysteretic spring (Plastic) contact model for a sweep tool operating in a cohesionless soil. Soil Tillage Research, 2014; 144: 220–227.

Yang L, Peng J, Yang H Y. Three-dimensional growth modeling of rice root based on differential l-system. Transaction of the CSAM, 2019; 50(10): 208–214. (in Chinese)

Yang S M. Design and experiment of the key components for rice cultivation. PhD dissertation. Harbin: Northeast Agricultural University, 2013. (in Chinese)

Xu S X, Xu X B, He Y K. Morphology and anatomy of rice. Beijing: Agricultural Press, 1984. (in Chinese)

Zhou Y Z, Wang W X, Cheng L M, Zeng Y J, Tan X M, Hu S X, et al. Research progress of weed occurrence and control in direct seeding rice field. Crops, 2019; 35(4): 1–9. (in Chinese)

Zhang J L, Wu S, Shi X G, Li B T, Tang L M. Influence of Barnyardgrass (Echinochloacrusgalli) on the growth of double-cropping paddy rice and its economic threshold. Acta Prataculturae Sinica, 2015; 24(8): 44–52.

Zhu W D, Zhou P G, He Y H, Yang J, Lin R H, Qi W Q, et al. Influence of Leptochloa Chinensis (L.) Nees. on growth and yield properties of rice and its economic threshold of control. Journal of Southern Agriculture, 2018; 49(5): 863–869. (in Chinese)

Tao G X, Wang J W, Zhou W Q, Niu C L, Zhao J K. Herbicidal mechanism and key components design for paddy weeding device. Transactions of the CSAM, 2015; 46(11): 57–63. (in Chinese)

Wu C Y, Zhang M, Jin C Q, Tu A. Design and experiment of 2BYS-6 type paddy weeding-cultivating machine. Transaction of the CSAM, 2009; 40(7): 51–54. (in Chinese)

Wang J F, Gao G B, Yan D W, Weng W. Design and experiment of electric control double row deep fertilizing weeding machine in paddy field. Transaction of the CSAM, 2018; 49(07): 46–57. (in Chinese)

Li N, Chen Z W, Zhu C B, Zhang C. System design and experiment of electric driven weeding robot. Transaction of the CSAM, 2016; 47(5): 15–20, 69. (in Chinese)

Zhang S, Du Y F, Zhu Z X, Mao E. Integrated control method of traction &slip ratio for rear-driving high-power tractors. Transactions of the CSAE, 2016; 32(12): 47–53. (in Chinese)

Siniakov P. The theory and calculation of soil farming machinery. In: Li Q G, Gao E G, Zhang X D, et al. (Ed.), editors. Beijing: China Agricultural Machinery Press, 1981; 256p. (in Chinese)

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. Transaction of the CSAM, 2017; 48(3): 49–56. (in Chinese)

Li Y X, Li F X, Xu X M, Shen C, Meng K, Chen J, et al. 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)

Ding Q S, Ren J, Adam B E, Zhao J. DEM analysis of subsoiling process in wet clayey paddy soil. Transaction of the CSAM, 2017; 48(3):38–48. (in Chinese)

Wu T, Huang W F, Chen X S, Ma X, Han Z, 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)

Waters J F, Lee S, Guduru P R. Mechanics of axisymmetric wavy surface adhesion: JKR-DMT transition solution. International Journal of Solids and Structures, 2008; 46(5): 1033–1042.

Wu L Y, Qi S, Song Y Q, Xin M J, Liu C H, Kong A J, et al. A DEM analysis on drag reduction characteristics of paddy field machinery surface with bionic micro architectures. Journal of Shenyang Agricultural University, 2017; 48(1): 55–62. (in Chinese)

Qi L, Liang Z W, Ma X, Tan Y. Validation and analysis of fluid-structure interaction between rotary harrow weeding roll and paddy soil. Transactions of the CSAE, 2015; 31(5): 29–37. (in Chinese)

Yu W J, Jia C, Di S T, Li K, Yuan H. Groundwater quality assessment based on comprehensive weight and improved matter-element extension evaluation model. Journal of Jilin University (Earth Science Edition), 2019; 49(2): 539–547. (in Chinese)