Development of a Batch Type Yield Monitoring System for Grain Combine Harvester
DOI:
https://doi.org/10.52151/jae2011484.1454Keywords:
Combine harvester, precision farming, grain yield sensor, yield monitorAbstract
Assessing soil and crop infield variability is crucial and first step of precision agriculture. In precision agriculture, after assessing the in-field variability, the same is taken care of through site-specific planting, site-specific nutrient and other input applications. Batch type yield monitor was developed having load cell of capacity 700 kg with drum size 125x85x80 cm for grain combines to measure the spatial variation of grains for use as single unit or by putting directly in trailer. Combine mounted batch type yield monitor was also developed by fitting an auxiliary tank of size 145×100×85 cm in the main tank and load cell at the bottom of the auxiliary tank. The yield data is displayed over a display unit installed near the driver seat. Yield variability of three different locations having CV of 5.46%, 27.56% and 35.34% were observed during the evaluation of batch type yield monitor. The systems are useful for small and marginal fields because of its low cost and can be used for any crop, or any combine. Yield monitor information can also be geographically referenced for generation of yield maps, which provide year-to-year comparisons of high- and low-yielding areas of a field throughout a crop rotation sequence for better management.
References
Chosa T; Shibata Y; Omine M; Toriyama K; Araki K. 2004. A study on yield monitoring system for head-feeding combines (Part 3) (in Japanese). J. Japanese Soc. of Agric. Machinery, 66(2), 137-144.
Daberkow S G; McBride W D. 1998. Adoption of precision agriculture technologies by U.S. corn producers. J. Agribus, 16(2), 151-168.
Diker K; Heermann D F; Bausch W C; Wright D K. 2002. Relationship between yield monitor and remotely sensed data for corn. ASAE Paper No. 021164, St. Joseph, Mich., ASAE.
Lowenberg-De Boer J. 2003. Precision farming or convenience agriculture. http://www.regional.org.au/au/asa/2003/i/6/lowenberg.htm/. Accessed on 30.04.2010.
Norton G; Swinton G. 2000. Invited paper presentation at the XXIV international association of agricultural economists meeting at Berlin, Germany.
Pierce F J. 1997. Yield mapping. Resource Magazine, 4(2), 9-10.
Samra J S; Rajput R K; Katyal V. 1992. Structured heterogeneity of soil pH and grain yield of rice and wheat grown in a sodic soil. Agronomy J., 84, 877-881.
Sharma V K; Singh K; Panesar B S. 1998. Custom hiring of agricultural machinery and its future scope. Agric. Engng. Today, 17(3&4), 68-72.
Singh J; Grover D K. 2002. The optimum nutritional requirement of rice crop in Punjab. Advanced Training course on nutrient and water management in crops and cropping system, PAU, Ludhiana (A Compendium of Lectures), 57-61.
Singh M; Shukla L N. 2005. Sowing performance of experimental no-till drill with straw thrower attachment in combine harvested paddy field. J. Res. Punjab Agric. Univ., 42(4), 463-73.
Singh S. 2002. Energy requirements for an efficient crop production with particular reference to nutrients and water. Advanced Training course on nutrient and water management in crops and cropping system, PAU, Ludhiana (A Compendium of Lectures), 93-100.
Stafford J V; Ambler B; Smith M P. 1991. Sensing and mapping grain yield variation. In: Proceedings of the 1991 Symposium on Automated Agriculture for the 21st Century, 16–17 December (ASAE, Chicago, IL), 356–365.
Wilhem N. 2000. Personal communication. Centre for Agricultural Management, University of the Free State, Bloemfontein, South Africa.
Yadav G S; Kumar D; Shivay Y S; Singh H. 2010. Zincenriched urea improves grain yield and quality of aromatic rice. Better Crops, 94(2), 6-7.
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