Traditional passive ground wheel drive of peanut planters has displayed poor high-speed seeding performance and the slippage caused in case of sticky and wet soil. Given this, an integrated electric-driven precision seed metering device and controller were designed, which features the application of improved fuzzy PID algorithm. Based on a small peanut planter with one ridge width and duplicate rows, the servo motor drive is used to replace the traditional passive ground wheel. In addition, the satellite speed measurement is employed to complete the electric driving and controlling modification of the seed meter and precise seeding control. A working process mathematical model for the peanut metering device was established to conduct motor speed and field tests which aim at comparing performances between the conventional and the improved fuzzy PID controls. The motor speed trial shows that the average error of the actual speed of the improved fuzzy PID motor was ±1 rad/min, and the coefficient of variation was less than 1%. Against the conventional one, it can better suppress overshoot and improve the response speed. The stable output speed can still be obtained even in case of step changes. Field tests show that when working at medium and low speeds, the qualified rate of plant spacing was greater than 98%, and the rate of missed sowing is <2%; while working at high speed, the qualified rate was greater than 94%, and the rate of missed sowing was less than 4%. The average plant spacing qualification rate of the seed device increased by 6.72%; compared with other electric-driven peanut seed meters, the plant spacing qualification rate increased by 4% during high-speed sowing. In summary, this study has provided an effective technical reference for high-speed precision planting of peanuts.
Keywords: peanut planter, precision seeding, control system, improved fuzzy PID
DOI: 10.25165/j.ijabe.20231601.7859

Citation: Yu Y, Hu Y R, Shang S Q, Diao L S, Ge R C, Zhang X. Design of motor-driven precision seed-metering device with improved fuzzy PID controller for small peanut planters. Int J Agric & Biol Eng, 2023; 16(1): 136–144.

peanut planter, precision seeding, control system, improved fuzzy PID

Gu F W, Hu Z C, Peng B L, Xie H X, Hu L L. General situation and mechanization development strategy of peanut production in China. Journal of Chinese Agricultural Mechanization, 2010; 3: 7–10. (in Chinese)

Cui T, Han D D, Yin X W, Li K H, Xiao L L, Yang L. Design and experiment of inside-filling air-blowing maize precision seed metering device. Transactions of the CSAE, 2017; 33(1): 8–16. (in Chinese)

Chen J, Zhao C J, Jones G, Yang H, Li Z H, Yang G J. Effect and economic benefit of precision seeding and laser land leveling for winter wheat in the middle of China. Artificial Intelligence in Agriculture, 2022; 6: 1–9.

Yuan Y W, Bai H J, Fang X F, Wang D C, Zhou L M, Niu K. Research progress on maize seeding and its measurement and control technology. Transactions of the CSAM, 2018; 49(9): 1–18. (in Chinese)

Yang X H, Yang Y G. Study on the compound shaped-hole structure for the peanut seeding device. Proceedings of the Institution of Mechanical Engineers, Part C: Journal of Mechanical Engineering Science, 2015; 229(4): 765–770.

Zhao X S, Ran W J, Hao J J, Bai W J, Yang X L. Design and experiment of the double-seed hole seeding precision seed metering device for peanuts. Int J Agric & Biol Eng, 2022; 15(3): 107–114.

Qi B. Study on pneumatic spoon type peanut precision seed-metering device. Master dissertation. Xinjiang: Shihezi University, 2020; 64p. (in Chinese)

Zhu T, Cong J L, Qi B B, Wu M C, Peng X Y, Wang Y S. Design and test of mechanical-pneumatic combined peanut precision seed-metering devices. China Mechanical Engineering, 2020; 31(21): 2592–2600. (in Chinese)

Sun Y T, Tian L Z, Shang S Q, Yang R B, Wang Y Y, Zhao J L. Experimental research on inside-filling metering device for peanut seeder. Transactions of the CSAE, 2012; 28(S2): 84–89. (in Chinese)

Fu W Q, Gao N N, An X F, Zhang J X. Study on precision application rate technology for maize no-tillage planter in North China Plain. IFAC-PapersOnLine, 2018; 51(17): 412–417.

Yang L, He X T, Cui T, Zhang D X, Shi S, Zhang R. Development of mechatronic driving system for seed meters equipped on conventional precision corn planter. Int J Agric & Biol Eng, 2015; 8(4): 1–9.

Cheng W D, Zhang G H, Ruan P Y, Diao P S, Jin C Q. Application review on electric-driven seed metering device of domestic precision seeder for maize or soybean. Journal of Chinese Agricultural Mechanization, 2017; 38(8): 13–16. (in Chinese)

Zhang C L, Wu R, Chen L Q. Design and test of electronic control seeding system for maize. Transactions of the CSAM, 2017; 48(2): 51–59. (in Chinese)

Ding X L, Li P J, Zhao L X, Wang C Y, Li Y B, Chen N C. Research and design of intelligent control and precision sowing simulation system for wheat. Journal of Intelligent & Fuzzy Systems, 2016; 31(4): 2313–2320.

Xie C J, Zhang D X, Yang L, Cui T, He X T, Du Z H. Precision seeding parameter monitoring system based on laser sensor and wireless serial port communication. Computers and Electronics in Agriculture, 2021; 190: 106429. doi: 10.1016/j.compag.2021.106429.

Wang S, Yu Y C, Yang C, Liu L, Zhang Y, Zhang Z. Experiment and research of seeding electromechanical control seeding system based on fuzzy control strategy. Journal of Intelligent and Fuzzy Systems, 2020; 38(1): 453–462.

Cay A, Kocabiyik H, May S. Development of an electro-mechanic control system for seed-metering unit of single seed corn planters Part I: Design and laboratory simulation. Computers and Electronics in Agriculture, 2018; 144: 71–79.

He X T, Ding Y Q, Zhang D X, Yang L, Cui T, Zhong X J. Development of a variable-rate seeding control system for corn planters Part II: Field performance. Computers and Electronics in Agriculture, 2019; 162: 309–317.

Jiang C. Study on intelligent control system for corn precision seeder. Master dissertation. Shandong: Shandong University of Technology, 2015. 76 p. (in Chinese)

Yin X, Noguchi N, Yang T X, Jin C Q. Development and evaluation of a low-cost precision seeding control system for a corn drill. Int J Agric & Biol Eng, 2018; 11(5): 95–99.

Cay A, Kocabiyik H, May S. Development of an electro-mechanic control system for seed-metering unit of single seed corn planters Part II: Field performance. Computers and Electronics in Agriculture, 2018; 145: 11–17.

He X T, Ding Y Q, Zhang D X, Yang L, Cui T, Wei J T. Design and evaluation of PID electronic control system for seed meters for maize precision planting. Transactions of the CSAE, 2017; 33(17): 28–33.

Ding Y Q, Yang L, Zhang D X, Cui T, Li Y H, Zhong X J, et al. Novel low-cost control system for large high-speed corn precision planters. Int J Agric & Biol Eng, 2021; 14(2): 151–158.

Chen L, Xie B B, Li Z D, Yang L, Chen Y X. Design of control system of maize precision seeding based on double closed loop PID fuzzy algorithm. Transactions of the CSAE, 2018; 34(9): 33–41. (in Chinese)

Yang S, Wang X, Gao Y Y, Zhao X G, Dou H J, Zhao C J. Design and experiment of motor driving bus control system for corn vacuum seed meter. Transactions of the CSAM, 2019; 50(2): 57–67. (in Chinese)

Zhang J, Tang F S, Liu J, Zang X W, Dong W Z, Zhang Z X. Flowering phenology and fruiting characteristics of summer peanut under different planting systems. Chinese Journal of Eco-Agriculture, 2015; 8: 979–986. (in Chinese)

Ding Y Q, Yang L, Zhang D X, Cui T, He X T, Zhong X J. Control system of motor-driving maize precision planter based on GPS speed measurement. Transactions of the CSAM, 2018; 49(8): 42–49. (in Chinese)

Xie C J, Zhang D X, Yang L, Tao C, Yu T C, Wang D C, et al. Experimental analysis on the variation law of sensor monitoring accuracy under different seeding speed and seeding spacing. Computers and Electronics in Agriculture, 2021, 189: 106369. doi: 10.1016/j.compag. 2021.106369.

Liu W, Hu J P, Zhao X S, Pan H R, Lakhiar I A, Wang W. Development and experimental analysis of a seeding quantity sensor for the precision seeding of small seeds. Sensors, 2019; 19(23): 5191. doi:10.3390/s19235191.

Li L L, Zhang R R, Chen L P, Yi T C, Xu G, Xue D X. Development of sensor system for real-time measurement of droplet deposition of agricultural sprayers. Int J Agric & Biol Eng, 2021; 14(5): 19–26.

Wang G, Sun W, Chen L D, Chen L D, Zhang H, Liu X. Realization of an integrated seeding and compensating potato planter based on one-way clutch. Int J Agric & Biol Eng, 2020; 13(3): 79–87.

He Z H, Gao W L, He X K, Wang M J, Liu Y L, Song Y. Fuzzy intelligent control method for improving flight attitude stability of plant protection quadrotor UAV. Int J Agric & Biol Eng, 2019; 12(6): 110–115.

Somwanshi D, Bundele M, Kumar G, Parashar G. Comparison of fuzzy-PID and PID controller for speed control of DC motor using LabVIEW. Procedia Computer Science, 2019; 152: 252–260.

Akbari-Hasanjani R, Javadi S, Sabbaghi-Nadooshan R. DC motor speed control by self-tuning fuzzy PID algorithm. Transactions of the Institute of Measurement and Control, 2015; 37(2): 164–176.

You Z C, Huang C H, Yang S M. Online current loop tuning for permanent magnet synchronous servo motor drives with deadbeat current control. Energies, 2019; 12(18): 3555. doi: 10.3390/en12183555.

GB/T 6973-2005. Test methods for single seed (precision) seeders. Chinese Standard, 2005. (in Chinese)