Seeding is an important part of improving corn yield. Currently, seed guide tubes are mostly used as transportdevices. But the existing seed guide tubes cannot meet the requirements or achieve the goal of fixing the seed falling trajectory.A seed collision phenomenon occurs occasionally. So, in response to the problems that the seeds and seed guide tube collide orbounce under high speed operation, which results in a lower sowing qualification rate and poor spacing uniformity, a seedreceiving and conveying system comprising a belt-type high-speed corn seed guiding device was designed and optimized, tomeet the needs of high-speed precision sowing operations and improve the spacing uniformity.The factors affecting the seedconveying performance were obtained by analyzing the mechanical properties of the seeds at various movement stages. Thesefactors were the number of seed cavities between adjacent seeds, the forward speed, the height from the ground, and theinstallation angle. Single factor simulation experiments were conducted by selecting the paddle spacing as the test factor andusing the pass rate, reseeding rate, omission rate and coefficient of variation as the evaluation indexes to investigate theinfluence of the paddle spacing on the seed guide performance of the device and further determine the structural parameters ofthe paddle belt. Orthogonal rotation combination tests of three factors and five levels were also conducted through benchtesting.Then the test outcomes were optimized. The results indicated that the best results were obtained when the number ofseed cavity intervals between adjacent seeds was 5.16, the installation angle was 79.40°, and the height from the ground was31.84 mm. At this time, the qualified rate was 98.49%, the repeated sowing rate was 0.48%, the missed sowing rate was 1.03%,and the coefficient of variation was 6.80%. Experiments were used to validate the optimization results, and all of the obtainedindex data satisfied the criteria for accurate and quick corn sowing. The study’s findings can serve as a theoretical foundationfor a belt-type high-speed corn seed guiding device optimization test.
Keywords: corn, high-speed sowing, belt-type seed guide device, test
DOI: 10.25165/j.ijabe.20241702.8427

Citation: Li Y F, Zhou W Q, Ma C C, Feng Z H, Wang J W, Yi S J, et al. Design and optimization of the seed conveying systemfor belt-type high-speed corn seed guiding device. Int J Agric & Biol Eng, 2024; 17(2): 123–131

corn, high-speed sowing, belt-type seed guide device, test

Li Y H, Yang L, Zhang D X, Cui T, He X T, Du Z H, et al. Performance analysis and structure optimization of the maize precision metering device with air suction at high-speed condition. Transactions of the CSAE, 2022; 38(8): 1–11. (in Chinese)

Yang W. Research on key technologies and equipment for precision sowing of maize breeding. PhD thesis, Chinese Academy of Agricultural Mechanization Sciences, Beijing, China, 2019. (in Chinese)

Yang L, Yan B X, Cui T, Yu Y M, He X T, Liu Q W. Global overview of research progress and development of precision maize planters. Int J Agric & Biol Eng, 2016; 9(1): 9–26.

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 L, Yan B X, Zhang D X, Zhang T L, Wang Y X, Cui T. Research progress on precision planting technology of maize. Transactions of the CSAM, 2016; 47(11): 38–48. (in Chinese)

Hou L Y, Zhang X F, Feng G, Li Z, Zhang Y B, Cao N. Arbuscular mycorrhizal enhancement of phosphorus uptake and yields of maize under high planting density in the black soil region of China. Scientific Reports, 2021; 11(1): 1–11. (in Chinese)

Tang H, Xu C S, Wang Z M, Wang Q, Wang J W. Optimized design, monitoring system development and experiment for a long-belt finger-clip precision corn seed metering device. Frontiers in Plant Science, 2022; 13: 814747.

Zhang B F, Liu D, Xi X B, Zhang Y F, Chen C, Qu J W, et al. The analysis of the applications of crop seed tape sowing technology and equipment: A review. Applied Sciences, 2021; 11(23): 11228.

Searle C L, Kocher M F, Smith J A, Blankenship E E. Field slope effects on uniformity of corn seed spacing for three precision planter metering systems. Applied Engineering in Agriculture, 2008; 24(5): 581–586.

Zhou B D, Li Y X, Zhang C, Cao L W, Li C S, Xie S J. Potato planter and planting technology: A review of recent developments. Agriculture, 2022; 12(10): 1600.

Kovács P, Casteel S N. Evaluation of a high‐speed planter in soybean production. Agronomy Journal, 2023; 115(3): 1174–1187.

John Deere. ExactEmerge high-speed planter. https://www.deere.com/en/planting-and-seeding-equipment/planters/exactemerge-high-speed-planter/.

Wei M J, Diao P S, Wang W J. Design and experiment of the seed delivery device with a rotating brush wheel for precision seeder. Engenharia Agrícola, 2022; 42(6): e20220089.

Nielsen R L. Stand establishment variability in corn. Proceedings of the Integrated Crop Management Conference. Iowa State University, Digital Press, 1993.

Zhu H B, Wu X, Bai L Z, Li R N, Guo G, Jin Q, et al. Design and experiment of a soybean shaftless spiral seed discharge and seed delivery device. Scientific Reports, 2023; 13(1): 20751.

Chen X G, Zhong L M. Design and test on belt-type seed delivery of air-suction metering device. Transactions of the CSAE, 2012; 28(22): 8–15.

Liu R. , Liu L J, Li Y J, Liu Z J, Zhao J W, Liu Y Q, et al. Numerical simulation of seed-movement characteristics in new maize delivery device. Agriculture, 2022; 12(11): 1944.

Ma C C, Yi S J, Tao G X, Li Y F, Wang S, Wang G Y, et al. Research on receiving seeds performance of belt-type high-speed corn seed guiding device based on discrete element method. Agriculture, 2023; 13(5): 1085.

Jia H L, Chen Y L, Zhao J L, Guo M Z, Huang D Y, Zhuang J. Design and key parameter optimization of an agitated soybean seed metering device with horizontal seed filling. Int J Agric & Biol Eng, 2018; 11(2): 76–87.

Liu Q W, Cui T, Zhang D X, Yang L, Wang Y X, He X T, et al. Design and experimental study of seed precise delivery mechanism for high-speed maize planter. Int J Agric & Biol Eng, 2018; 11(4): 81–87.

Zhao X S, Bai W J, Li J C, Yu H L, Zhao D W, Yin B Z. Study on positive-negative pressure seed metering device for wide-seedling-strip-seeding. Int J Agric & Biol Eng, 2022; 15(6): 124–133.

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

Liu W, Zou S S, Xu X L, Gu Q Y, He W Z, Huang J, et al. Development of UAV-based shot seeding device for rice planting. Int J Agric & Biol Eng, 2022; 15(6): 1–7.

Zhang W X, Wang F Y. Parameter calibration of American ginseng seeds for discrete element simulation. Int J Agric & Biol Eng, 2022; 15(6): 16–22.

Esterhuizen M, Kim Y J. Effects of polypropylene, polyvinyl chloride, polyethylene terephthalate, polyurethane, high-density polyethylene, and polystyrene microplastic on Nelumbo nucifera (Lotus) in water and sediment. Environ Sci Pollut Res, 2022; 29(6): 17580–17590.

Gu F W, Zhao Y Q, Feng W, Hu Z C, Shi L L. Simulation analysis and experimental validation of conveying device in uniform rushed straw throwing and seed-sowing machines using CFD-DEM coupled approach. Computers and Electronics in Agriculture, 2022; 193: 106720.

Lu J Q, Yang Y, Li Z H, Shang Q Q, Li J C, Liu Z Y. Design and experiment of an air-suction potato seed metering device. Int J Agric & Biol Eng, 2016; 9(5): 33–42.

Yazgi A, Degirmencioglu A. Measurement of seed spacing uniformity performance of a precision metering unit as function of the number of holes on vacuum plate. Measurement, 2014; 56: 128–135.

Liu Z Y, Xia J F, Hu M J, Du J, Luo C M, Zheng K. Design and analysis of a performance monitoring system for a seed metering device based on pulse width recognition. PloS One, 2021; 16(12): e0261593.

Önal S, Degirmencioglu A, Yazgi A. An evaluation of seed spacing accuracy of a vacuum type precision metering unit based on theoretical considerations and experiments. Turkish Journal of Agriculture and Forestry, 2012; 36(2): 133–144.

Lei X L, Hu H J, Yang W H, Liu L Y, Liao Q, Wang R. Seeding performance of air-assisted centralized seed-metering device for rapeseed. Int J Agric & Biol Eng, 2021; 14(5): 79–87.

Wang B L, Na Y, Liu J, Wang Z M. Design and evaluation of vacuum central drum seed metering device. Applied Sciences, 2022; 12(4); 2159.

Guo J, Yang Y, Memon M S, Tan C, Wang L Y, Tang P. Design and simulation for seeding performance of high-speed inclined corn metering device based on discrete element method (DEM). Scientific Reports, 2022; 12(1): 19415.

Sopyan I, Gozali D, Kurniawansyah I S, Guntina R K. Design-expert software (DOE): An application tool for optimization in pharmaceutical preparations formulation. International Journal of Applied Pharmaceutics, 2022; 14(4): 55–63.

Hossain M S, Jahan S, Rahman S A R, Rahman M, Shill D K, Paul S, et al. Design expert software assisted development and evaluation of empagliflozin and sitagliptin combination tablet with improved in-vivo anti-diabetic activities. Heliyon, 2023; 9(3): e14259.

Arpna I, Masheer K A. Box-Behnken design for optimization of formulation variables for controlled release gastroretentive tablet of verapamil hydrochlorid. International Journal of Applied Pharmaceutics, 2023; 15(1): 256–263.

Djaman K, Allen S, Djaman D S, Koudahe K, Irmak S, Puppala N, et al. Planting date and plant density effects on maize growth, yield and water use efficiency. Environmental Challenges, 2022; 6: 100417.

Zhang Y H, Xu Z G, Li J, Wang R. Optimum planting density improves resource use efficiency and yield stability of rainfed maize in semiarid climate. Frontiers in Plant Science, 2021; 12: 752606.

Clemente O G, Albajes R, Batuecas I, Achon M A. Planting period is the main factor for controlling maize rough dwarf disease. Scientific Reports, 2021; 11(1): 977.