Simulation and experiment on prediction of total rice seeds mass in vibrating tray for vacuum plate seeder
Abstract
Keywords: vacuum plate seeder, rice seeds, total mass, prediction method, vibrating tray, discrete element method
DOI: 10.25165/j.ijabe.20191205.4415
Citation: Zhao Z, Jin M Z, Tian C J, Qin F. Simulation and experiment on prediction of total rice seeds mass in vibrating tray for vacuum plate seeder. Int J Agric & Biol Eng, 2019; 12(5): 81–86.
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Yang Z Y, Li N, Ma J, Sun Y J, Xu H. High-yielding traits of heavy panicle varieties under triangle planting geometry: A new plant spatial configuration for hybrid rice in China. Field Crops Research, 2014; 168: 135–147.
Sun T, Shang W N, Cao H F, Zhang J B, Jin X Y. Effects of different seeding quantity on rice growing and yield. Chinese Agricultural Science Bulletin, 2005; 21(7): 134–137. (in Chinese)
Jiang X L, Li X Y, Chi Z Z, Wang S H, Yang F M, Zheng J G. Research on potted-tray grown rice seedling transplanting by machine. Agricultural Science & Technology, 2014; 15(11): 1923–1927.
Yi S J, Liu Y F, Wang C, Tao G X. Experimental study on the performance of bowl-tray rice precision seeder. Int J Agric & Biol Eng, 2014; 7(1): 17–25.
Gaikwad B B, Sirohi N P S. Design of a low-cost pneumatic seeder for nursery plug trays. Biosystems Engineering, 2008; 99: 322–329.
Movahedi E, Rrzvani M, Hemmat A. Design, development and evaluation of a pneumatic seeder for automatic planting of seeds in cellular trays. Journal of Agricultural Machinery, 2016; 4(1): 65–72.
Topakci M, Karayel D, Canakci M, Furat S, Uzun B. Sesame hill dropping performance of a vacuum seeder for different tillage practices. Applied engineering in agriculture, 2011; 27(2): 203–209.
Rathinakumari A C, Kumaran G S, Mandhar S C. Design and development of tray type vacuum seeder and tray type. Applied horticulture; 2005; 7(1): 49–51.
Karayel D. Performance of a modified precision vacuum seeder for no-till sowing of maize and soybean. Soil & Tillage Research, 2009; 104(1): 121–125.
Liu L J, Yang H, Ma S C. Experimental study on performance of pneumatic seeding system. Int J Agric & Biol Eng, 2016; 9(6): 84–90.
Masami F, Tadashi C, Yukiharu S, Takayuki T, Masahiro S, Hisashi H. Developing direct seeding cultivation using an air-assisted strip seeder. Japan Agricultural Research Quarterly, 2015; 49(3), 227–233.
He X, Wang Z M, Luo X W, Cao X M, Liu C B, Zang Y. General structure design and field experiment of pneumatic rice direct-seeder. Int J Agric & Biol Eng, 2017; 10(6): 31–41.
Chen J, Gong Z Q, Li Y M, Li J H, Xu Y. Experimental study on nursing seedlings of super rice precision seeder device. Transactions of the CSAM, 2015; 46(1): 73–78. (in Chinese)
Yazgi A, Degirmencioglu A. Optimisation of the seed spacing uniformity performance of a vacuum-type precision seeder using response surface methodology. Biosystems Engineering, 2007; 97(3): 347–356.
Abdolahzare Z, Asoodar M A, Kazemi N, Rahnama M, Mehdizadeh S A. Optimization of the most important operational parameters of a pneumatic seeder using real-time monitoring for Cucumber and Watermelon seeds. Journal of Agricultural Machinery, 2016; 1: 35–48.
Liu C L, Song J N, Wang J C, Wang C. Analysis of flow field simulation on vacuum seed-metering components of precision metering device with sucker. Journal of China Agricultural University, 2014; 45(6): 92–97. (in Chinese)
Gaikwad B B, Sirohi N P S. Design of a low-cost pneumatic seeder for nursery plug trays. Biosystems Engineering, 2008; 99(3): 322–329.
Zhao Z, Tian C J, Huang H D, Yang S X. Optimization of suction plate structure and seed pickup performance for precision nursery seeder. International Agricultural Engineering Journal, 2019; 28(1): 153–161.
Zhao Z, Tian C J, Wu Y F, Huang H D. Dynamic simulation of seed pick-up process and parameter optimization on vacuum plate seeder for rice. Transactions of CSAE, 2018; 34(7): 38–44. (in Chinese)
Chen J, Li J H, Li Y M, Gong Z Q. Analysis of suction height and seed-adding device for suction-vibration precision seeder. Transactions of the CSAM, 2013; 44(1): 67–71. (in Chinese)
Zhao Z, Wu Y F, Yin J J, Tang Z. Monitoring method of rice seeds mass in vibrating tray for vacuum-panel precision seeder. Computers and Electronics in Agriculture, 2015; 114: 25–31.
Tijskens E, Ramon H, Baerdemaeker De J. Discrete element modelling for process simulation in agriculture. Journal of Sound and Vibration, 2003; 266: 493–514.
Josephine B, Ambrose R, Mark C, Ronaldo M, Dirk M. Applications of discrete element method in modeling of grain postharvest operations. Food Engineering Reviews, 2014; 6(4): 128–149.
Horabik J, Molenda M. Parameters and contact models for DEM simulations of agricultural granular materials: A review. Biosystems Engineering, 2016; 147: 206–225.
Wang J W, Tang H, Wang J F, Li X, Huang H N. Optimization design and experiment on ripple surface type pickup finger of precision maize seed metering device. Int J Agric & Biol Eng, 2017; 10(1): 61–71.
Zhao Z, Jin M Z, Tian C J, Yang S X. Prediction of seed distribution in rectangular vibrating tray using grey model and artificial neural network. Biosystems Engineering, 2018; 175: 194–205.
Raji A O, Favier J F. Model for the deformation in agricultural and food particulate materials under bulk compressive loading using discrete element method. I: Theory, model development and validation. Journal of Food Engineering, 2004; 64: 359–371.
Li H C, Li Y M, Gao F, Zhao Z, Xu L Z. CFD-DEM simulation of material motion in air-and-screen cleaning device. Computers and Electronics in Agriculture, 2012; 88: 111–119.
Varnamkhasti M G, Mobli H, Jafari A, et al. Some physical properties of rough rice grain. Journal of Cereal Science, 2008; 47(3): 496–501.
Auger F, Hilairet M, Guerrero J M, Monmasson E, Orlowska-Kowalska T, Katsura S. Industrial applications of the Kalman filter: A review. IEEE Transactions on Industrial Electronics, 2013; 60(12): 5458–5471.
Martin B, Nick W. The Kalman filter for linear systems on time scales. Journal of Mathematical Analysis and Applications, 2013; 406: 419–436.
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