Potato planter test bed based on capacitive precision seed-monitoring and miss-seeding compensation system

Hua Zhang, Wuyun Zhao, Wei Sun, Guanping Wang, Xiaolong Liu, Bin Feng, Linrong Shi, Yan Liu, Hongling Li

Abstract


Potato seed-monitoring is the premise of its precise planting. But, for anti-dust, anti-vibration performance and durability, the existing photoelectric monitoring schemes have obvious congenital defects. So, a capacitive precision seed-monitoring idea was proposed in this study. Its theoretical basis is that the variation of dielectric between the capacitor plates will inevitably induce the fluctuation of the detected capacitance value. Therefore, the construction of a space capacitance sensor, and the acquisition of the net capacitance fluctuation caused by the seed spoon passing through the space area of the capacitor plates, were the core focuses of this study. Firstly, the system theory and working principle was introduced. Next, a space capacitance sensor that meets all the requirements was analyzed and constructed. And then, its spatial arrangement was described in detail, and most important of all, the technology roadmap of the net capacitance fluctuation measurement were put forward. For this purpose, MAX038 and GD32F407 were selected to work together to measure the capacitance. From this way, the top value of the space capacitance when a spoon passed through the space capacitance sensor was detected, at the same time, the corresponding grating encoder information was also recorded, so, the net capacitance fluctuation of this process was calculated. Based on this result, normal-seeding, miss-seeding, and multi-seeding were identified. More subtly, with the cooperation of the grating encoder, the position of the seed-metering monitoring point was configured freely. Just for miss-seeding, a predictive impact compensation concept was suggested. Based on the theories above, the software core links related to seed-monitoring and compensation control were analyzed. Finally, a potato planter test bed based on this study was built. Taking the Long-7 cutting potato as test samples, it was found that, the capacitance measurement error was no higher than 0.6%; no misjudgment on miss-seeding was found, however, for normal-seeding and multi-seeding, there was a small amount of identification of the opposite kind was found, but not more than 1.0% and 1.5%, respectively. Because of the flexibility of the seed-metering monitoring point layout, the predictive impact compensation can also be arranged according to actual needs, and the mechanism of the impact compensation system is simple and direct, which makes it cheap and fast. Nevertheless, a lower compensating seed potato tank filling rate is conducive to the average compensation success rate at an acceptable level. This research has laid the engineering foundation for the industrial application of potato non-photoelectric seed-metering monitoring and miss-seeding compensation.
Keywords: potato planter, capacitive precision seed-monitoring, space capacitance sensor, miss-seeding compensation system
DOI: 10.25165/j.ijane.20221506.6785

Citation: Zhang H, Zhao W Y, Sun W, Wang G P, Liu X L, Feng B, et al. Potato planter test bed based on capacitive precision seed-monitoring and miss-seeding compensation system. Int J Agric & Biol Eng, 2022; 15(6): 104–112.

Keywords


potato planter, capacitive precision seed-monitoring, space capacitance sensor, miss-seeding compensation system

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References


Dai F, Song X F, Zhao W Y, Shi R J, Zhang F W, Zhang X K. Mechanism analysis and performance improvement of mechanized ridge forming of whole plastic film mulched double ridges. Int J Agric & Biol Eng, 2020; 13(5): 107-116.

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

Sun W, Simionescu P A. Parameter analysis and field tests of a double crank multi-rod under plastic-film hill-drop mechanism potato planter. American Journal of Potato Research, 2020; 97: 256–264.

Cho Y J, Choi I S, Kim J D, Oh J W, Lee D H. Performance test of fully automatic potato seeding machine by in-situ process of cutting seeds. Journal of Biosystems Engineering, 2017; 42(3): 147–154.

Ebrahem I Z, Ayman A E, Guidetti R. A new small potato planter for Egyptian agriculture. Journal of Agricultural Engineering, 2011; 3(3): 7-13.

Sun W, Liu X L, Zhang H, Wang H C, Tian B. Design of potato casingsoil planter in all-in-one machine combined with fertilizing, sowing, ridging, complete film mulching and planting line covering. Transactions of the CSAE, 2017; 33(20): 14-22. (in Chinese)

Aboegela, M A, EI-Ghobashy H M, Shaban Y A. Development a single row potato planter for small holdings. Journal of Soil Sciences and Agricultural Engineering, 2021; 12(3):137-143.

Li D, Sun W, Shi L R, Zhang H, Liu X L, Wu J M. Parameter simulation design and experiment of crossing device of covering soil on film. Agricultural Research in the Arid Areas, 2018; 36(1): 281-287. (in Chinese)

Yang H G, Liu Z S, Ni Z W, Lin L C, Yang R B. Design and test of 2CM-4 type potato planter. Journal of Qingdao Agricultural University (Natural Science), 2017; 32(2): 137-140. (in Chinese)

Liu Q W, Wu J M, Wang D, Sun W, Wang G P, Shi L R. Current status and progress of the potato seeder. Journal of Agricultural Mechanization Research, 2013; 35(6): 238-241. (in Chinese)

Leemans V, Destain M F. A computer-vision based precision seed drill guidance assistance. Computers and Electronics in Agriculture, 2007; 59(1-2): 1-12.

Samseemoung G, Soni P, Jayasuriya H P W, Salokhe V M. Application of low altitude remote sensing (LARS) platform for monitoring crop growth and weed infestation in a soybean plantation. Precision Agriculture, 2012; 13(6): 611-627.

Hörbe T A N, Amado T J C, Ferreira A O, Alba P J. Optimization of corn plant population according to management zones in Southern Brazil. Precision Agriculture, 2013; 14(4): 450-465.

Ministry of Agriculture and Rural Areas of the People's Republic of China (MARA). Available: http://www.moa.gov.cn/ztzl/mls/mlshydt/201501/t20150107_4325191.htm. Accessed on [2021-05-23].

Basso B, Fiorentino C, Cammarano D, Schulthess U. Variable rate nitrogen fertilizer response in wheat using remote sensing. Precision Agriculture, 2016; 17(2): 168-182.

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

Sun W, Wang G P, Wu J M. Design and experiment on loss sowing testing and compensation system of spoon-chain potato metering device. Transactions of the CSAE, 2016; 32(11): 8-15. (in Chinese)

Wang G P, Sun W. Development of a kind of potato loss sowing detection and compensation device. Research of Agricultural Modernization, 2016; 37(5): 1008-1014. (in Chinese)

Yang H, Wang G P, Sun W, Zhu L, Yang S, Wang C J, et al. Design and test of a new type of potato seeder with integrated sowing and compensating. Agricultural Research in the Arid Areas, 2020; 38(6): 260-268. (in Chinese)

Wang G P, Sun W, Zhang H, Liu X L, Li H L, Yang X P, et al. Research on a kind of seeding-monitoring and compensating control system for potato planter without additional seed-metering channel. Computers and Electronics in Agriculture, 2020; 177: 105681.

Fan J J. Research on potato seeder based on image processing. Master dissertation. Xi’an: Chang’an University, 2018; 66p. (in Chinese)

Niu K, Zhou L M, Yuan Y W, Liu Y C, Fang F X. Design and experiment on automatic compensation system of spoon-chain potato metering device. Transactions of the CSAM, 2016; 47(S1): 76-83. (in Chinese)




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