This paper presented a novel variable rate fertilization system based on the method of adjusting the active feed-roll length of a fluted roller. The feasibility of this method was discussed using analysis of the fluted roller model. One seed drill produced by Kuhn Company (France), which could sow and fertilize simultaneously, was used as a test platform to implement the mechanical structure of variable rate fertilization. The design methods for the variable rate fertilization mechanical structure and actuator were introduced in detail. A low-cost and stable embedded support decision subsystem and corresponding software were developed. The support decision subsystem is based on grid management. Each grid field cell contains information about corresponding spatial position and fertilizer application rate. A SpatiaLite database was employed to solve the spatial location search and spatial data query. Experiments were conducted to evaluate the fertilization uniformity and dynamic response time. The average value of coefficient of variation is 8.4% in five different active feed-roll lengths which reflects good uniformity. The dynamic response times for the adjustment of variable rate fertilization system from 204 kg/hm2 to 319 kg/hm2 and 319 kg/hm2 to 204 kg/hm2 are about 4.2 s. The results suggest that the variable rate fertilization system performs well in dynamic adjustment and stability.
Keywords: precision agriculture, variable rate fertilization, fluted roller, active feed-roll length, servo drive, embedded system
DOI: 10.3965/j.ijabe.20150804.1644

Citation: Su N, Xu T S, Song L T, Wang R J, Wei Y Y. Variable rate fertilization system with adjustable active feed-roll length. Int J Agric & Biol Eng, 2015; 8(4): 19－26.

precision agriculture, variable rate fertilization, fluted roller, active feed-roll length, servo drive, embedded system

Yang C, Everitt J H, Bradford J M. Comparisons of uniform and variable rate nitrogen and phosphorus fertilizer applications for grain sorghum. Transactions of the ASAE, 2001; 44 (2): 201–210.

McBratney A, Whelan B, Ancev T. Future directions of precision agriculture. Precision Agriculture, 2005; 6(1): 7–23.

Du R C, Gong B C, Liu N N, Wang C C, Yang Z D, Ma M J. Design and experiment on intelligent fuzzy monitoring system for corn planters. Int J Agric & Biol Eng, 2013; 6(3): 11–18.

Farooque A A, Zaman Q U, Schumann A W, Madani A, Percival D C. Delineating management zones for site specific fertilization in wild blueberry fields. Applied Engineering in Agriculture, 2012; 28(1): 57–70.

Koch B, Khosla R, Frasier W M, Westfall D G, Inman D. Economic feasibility of variable-rate nitrogen application utilizing site-specific management zones. Agronomy Journal, 2004; 96(6): 1572–1580.

Lü H, Yu J, Fu H. Simulation of the operation of a fertilizer spreader based on an outer groove wheel using a discrete element method. Mathematical and Computer Modelling, 2013; 58(3): 842–851.

Wang X, Zhao C J, Meng Z J, Chen L P, Pan Y C, Xue X Z.

Design and experiment of variable rate fertilizer applicator. Transactions of the CSAE, 2004; 20(5): 114–117. (in Chinese with English abstract)

Thomson S J, Smith L A, Hanks J E. Evaluation of application accuracy and performance of a hydraulically operated variable-rate aerial application system. Transactions of the ASABE, 2009; 52(3): 715–722.

Ess D R, Morgan M T, Parson S D. Implementing site-specific management: map-versus sensor-based variable rate application. Technical Report: Pub. No. SSM-2-W. 2001.

Yuan J, Liu C L, Li Y M, Zeng Q B, Zha X F. Gaussian processes based bivariate control parameters optimization of variable-rate granular fertilizer applicator. Computers and Electronics in Agriculture, 2010; 70(1): 33–41.

Ang K H, Chong G, Li Y. PID control system analysis, design, and technology. IEEE Transactions on Control Systems Technology, 2005; 13(4): 559–576.

Furieri A. SpatiaLite Cookbook. 2011; p151.

Kim Y J, Kim H J, Ryu K H, Rhee J Y. Fertiliser application performance of a variable-rate pneumatic granular applicator for rice production. Biosystems Engineering, 2008; 100(4): 498–510.

Fulton J P, Shearer S A, Higgins S F, Hancock D W, Stombaugh T S. Distribution pattern variability of granular VRT applicators. Transactions of the ASABE, 2005; 48(6): 2053–2064.

Maleki M R, Mouazen A M, De Ketelaere B, Ramon H, De Baerdemaeker J. On-the-go variable-rate phosphorus fertilisation based on a visible and near-infrared soil sensor. Biosystems Engineering, 2008; 99(1): 35–46.

Fulton J P, Shearer S A, Higgins S F, Darr M J, Stombaugh T S. Rate response assessment from various granular VRT applicators. Transactions of the ASAE, 2005; 48(6): 2095–2103.

Jafari M, Hemmat A, Sadeghi M. Development and performance assessment of a DC electric variable-rate controller for use on grain drills. Computers and Electronics in Agriculture, 2010; 73(1): 56–65.