A secondary seeding precision double-seed peanut hole seeding seed metering device was designed to improve the performance of the peanut planting equipment and provide a solution for problems on the high seed charge that can cause poor cavitation and uniformity easily. The main structure and operation parameters in terms of groove length, seed charge height, seed-bed belt speed, and rotation speed of the seed metering wheel were determined through theoretical analysis. Single-factor and orthogonal tests were carried out through the JPS-12 seed metering device test bench, and the peanut variety Jinonghua-3 was selected as the test object. The single hole double-seed rate, qualified rate, the variation coefficient of hole spacing, and hole rate were chosen for evaluating the working performance. The results of the single-factor test showed that the seed metering performance is mainly affected by the groove length, the speed of the seed-bed belt and the rotation speed of the seed metering wheel, and the influence of the cavitation rate is minimal. The optimal seeding height is determined to be 40 mm. The results of the orthogonal test showed that the groove length was 27.3 mm, the seed-bed belt speed was 1.51 km/h, and the rotation speed of the seed metering wheel was 14.11 r/min. What’s more, a regression model based on the orthogonal test results was established, the qualified rate of the number of holes obtained after optimizing the model was 98.84%, the variation coefficient of hole spacing was 9.74%, and the hole rate was 1.40%. Notably, the working performances of the device can meet the requirement of precision seeding.
Keywords: peanut, precision, seed metering device, orthogonal test, regression method
DOI: 10.25165/j.ijabe.20221503.6608

Citation: 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.

peanut, precision, seed metering device, orthogonal test, regression method

Kang J M, Peng Q J, Zhang C Y, Zhang N N, Fang H M. Design and testing of a punching-on-film precision hole seeder for peanuts. Transactions of the ASABE, 2020; 63(6): 1685–1696.

Zhao Y F, Zhang C J, Meng Y, Wang M L, Wang Y F, Zhang X J, et al. Effects of calcium application on agronomic characters of peanut pods at development stage. Journal of peanut science, 2019; 48(1): 27–33, 57. (in Chinese)

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.

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.

Zhang K F, Zhang Z, Wang S, Yang C, Yu Y C, Li H. Design and experiment of electronic seeding system based on response surface method. International Journal of Computer Integrated Manufacturing, 2020; 33(10-11): 982–990.

Jin X Y, Sun S M, Zhang H B, Liang Y C, Yu X B. Design and research of 2BJZ-2 type corn single-grain precision seeder. Journal of Agricultural Mechanization Research, 2019; 41(3): 51–57. (in Chinese)

Ding Y, Wang L, Li Y W, Li D L. Model predictive control and its application in agricultural: A review. Computers and Electronics in Agriculture, 2018; 151: 104–117.

Jin X, Li Q W, Zhao K X, Zhao B, He Z T, Qiu Z M. Development and test an electric precision seeder for small-size vegetable seeds. Int J Agric & Biol Eng, 2019; 12(2): 75–81.

He X K, Bonds J, Langenakens J. Recent development of unmanned aerial vehicle for plant protection in East Asia. Int J Agric & Biol Eng, 2017; 10(3): 18–30.

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

Singh R C, Singh G, Saraswat D C. Optimisation of design and operational parameters of a pneumatic seed metering device for planting cottonseeds. Biosystems Engineering, 2005; 92(4): 429–438.

Zhang J L, Guo F, Yang D Q, Meng J J, Yang S, Wang X Y, et al. Effects of single-seed precision planting on population structure and yield of peanuts with super-high yield cultivation. Scientia Agricultura Sinica, 2015; 48(18): 3757–3766. (in Chinese)

Zhang Z M, Dai L X, Ci D W, Yang J S, Ding H, Qin F F, et al. Effects of planting density and planting method on growth, development, yield, and quality of peanut in saline-alkali land. Chinese Journal of Eco-Agriculture, 2016; 24(10): 1328–1338. (in Chinese)

Liao Y T, Wang L, Liao Q X. Design and test of an inside-filling pneumatic precision centralized seed-metering device for rapeseed. Int J Agric & Biol Eng, 2017; 10(2): 56–62.

Liao Q X, Lei X L, Liao Y T, Ding Y C, Zhang Q S, Wang L. Research progress of precision seeding for rapeseed. Transactions of the CSAM, 2017; 48(9): 1–16. (in Chinese)

Zhang T T, He X N, Wang Y Y, Shang S Q, Wang D W, Tong Q T. Study on air suction precision seeder for peanut. Journal of Agricultural Mechanization Research, 2017; 39(5): 68–74. (in Chinese)

Elebaid J I, Liao Q X, Wang L, Liao Y T, Yao L. Design and experiment of multi-row pneumatic precision metering device for rapeseed. Int J Agric & Biol Eng, 2018; 11(5): 116–123.

Yu J J, Liao Y T, Cong J L, Yang S, Liao Q X. Simulation analysis and match experiment on negative and positive pressures of pneumatic precision metering device for rapeseed. Int J Agric & Biol Eng, 2014; 7(3): 1–12.

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

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)

Yang Y G, Yang X M, Li C H. The improvement and motion simulation research of filling type vertical plate seed-metering device. Journal of Agricultural Mechanization Research, 2014; 36(4): 16–20. (in Chinese)

Song J L, Yang Z D, Yang S D, Zhang G H, Li H W. A novel inside-filling seed metering device. Journal of Agricultural Mechanization Research, 2013; 35(6): 90–93. (in Chinese)

Yang R B, Chai H H, Shang S Q. Performance of metering device with declined discon peanut seeder. Transactions of the CSAM, 2014; 45(6): 79–84. (in Chinese)

Chen T, Zhai C N, Xing Z Z, Guo X J, Zhang H D. Discrete element simulation study of seed metering process of inside-filling meter based on EDEM. Journal of Anhui Agricultural Sciences, 2016; 44(16): 250–253, 278. (in Chinese)

He Y H, Cong J L, Kan Z, Liu X Y. Design and simulation of cam contour curve of pneumatic precision metering device. Journal of Shihezi University (Natural Science), 2016; 34(3): 391–396. (in Chinese)

Luo X W, Zhang M H, Wang Z M, Zeng S, Zhou Z Y, Zang Y, et al. Combined hole seed metering device with adjustable seeding rate, 2012; Chinese Patent: CN102612904A. (in Chinese)

Chen X, Chen G L, Wang X D. Optimization design and test of the pore structure of peanut seed metering device. Journal of Zhongkai University of Agricultural Engineering, 2019; 32(1): 28–34. (in Chinese)

Wang B L, Wang Z M, Luo X W, Zhang M H, Fang L Y, Liu S C, et al. Design and experiment of wedge churning device for pneumatic cylinder-type seed metering device for hybrid rice. Transactions of the CSAE, 2019; 35(23): 1–8. (in Chinese)

Hebei Agricultural University. Seed metering devise with secondary seeding function, 2020; Chinese Patent: ZL201921327152.7. (in Chinese)

Hebei Agricultural University. Seed metering devise with secondary seeding function, 2019; Chinese Patent: CN201910755084.2. (in Chinese)

Lei X L, Zhang L, Yang H, Liu Y L, Li Y H, Luo M L. Design and experiment of the electric drive control system of precision centralized metering device for rapeseed. Journal of Anhui Agricultural University, 2020; 47(3): 472–479. (in Chinese)

NY/T987-2006. Operating quality grain film-covering hill-drop dill. Ministry of Agriculture, the People’s Republic of China, 2006. (in Chinese)