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Increasing the Speed of a Semi-Automatic Onion Transplanter with the Use of Simultaneous Planting of Multiple Seedlings

Document Type : Original Article

Abstract

A semi-automatic 9-row transplanter for bare root seedlings has recently been developed at the Isfahan Center for Agricultural Research that plants 80 seedlings/m2 using 9 operators at a capacity of 0.3 ha/d (8 h). Separating a single seedling from a bunch and dropping it into a distributer cell by hand takes 1 s on average. At a density of 700-800 thousand/ha, the travel speed should not exceed 6-8 cm/s, which is a limitation to improving machine field capacity. Increasing the speed to >8 cm/s to improve machine efficiency can only be achieved if more than one seedling is allocated to each cell. A randomized complete block design was used to drop 1, 2 and 3 seedlings per cell at speeds of 8, 12 and 16 cm/s, respectively, with manual transplanting as the control treatment. The treatments were compared for stand establishment, crop yield components, machine field capacity and economic benefit. The results showed that dropping two seedlings per cell and increasing speed 50% and produced a about a 24% increase in stand establishment and bulb yield compared to the single seedling/cell treatment. Three seedlings per cell produced a 53% increase in stand establishment but only about 17% improvement in bulb yield. This can be attributed to the smaller sizes and weights of the individual bulbs. The number of established seedlings in the 1 seedling per cell pattern produced results that were similar to the manual single transplanting treatment. Economic appraisal of treatments revealed that replacing 1 seedling per cell with 2 and 3 seedlings per cell produced a net increase in profits of 33% and 12%, respectively. The 2 and 3 seedlings per cell methods increased machine field capacity 50% and 100%, respectively. It can be concluded that, from the economic standpoint, 2 seedlings per cell is preferred over the 3 seedling per cell treatment; however when planting must be completed rapidly, the 3 seedling per cell treatment is also economically justified.

Keywords

References
Anon. 1985. U. S. Department of Agriculture. United States standard for grades of Bermuda–Granex–Grano type onions. U.S. Dept. Agric. Agr. Marketing Serv. Washington, D.C.
Brewster, J. L. 1994. Onions and Other Vegetable Alliums (Crop Production in Horticulture 3). CAB Int. Wallingford, UK. 236.
Chung, B. 1998. Multi-plant module transplants of bulb onions. Acta Hort. 247, 187-191.
Dereje, A., Derbew, B. and Getachew, T. 2012. Influence of bulb topping and intra row spacing on yield and quality of some shallot (Allium Cepa Var. Aggregatum) varieties at Anededworeda, western Amhara.  African J. Plant Scie. 6(6): 190-202.
Farhmand, S., Ahmadian, A. and Ghomashei, A. 2010.Evaluation of a gripper type transplanter in
bare-root seedlings of onion. Technical Report. Esfahan Agriculture Organization. (in Farsi)
Ghahramanian, G. 1998. Development of an onion transplanter. M. Sc. Thesis. Faculty of Agriculture, Shiraz University. Shiraz. Iran. (in Farsi)
Grant, D. G. and Carter B. V. 1994. The influence of cultural factors on the bulb of the onion
(Allium cepa L.) cultivar ‘Pukekohe Longkeeper’. Acta Hort. 433, 527-532.
Herison, C., Joseph, G., Masabni, G. and Bernard, H. Z. 1993. Increasing seedling density, age, and nitrogen fertilization increases onion yield. Hort Sci. 28(1): 23-25.
Kanton, R. A . L., Abbey, L., Hilla, R. G., Tabil, M. A. and January, N. D. 2002. Density affects plant development and yield of bulb onion (Allium cepa L.) in Northern Ghana. J. Veg. Crop Prod. 8, 15-27.
Peters, R. J., Kowithayakorn, T., Chalard, T. and Rabinowitch, H. D. 1994. The effect of date of harvest on shelf life of onions stored by hanging from leaves. Acta Hort. 358, 365-368.
Rumpel, J. and Felczynski, K. 2000. Effect of plant density on yield and bulb size of direct sown onions.  Acta Hort. 533, 179-185.
Russo, V. M. 2004. Greenhouse-grown transplants as an alternative to bare-root transplants for onions.  Hort Sci. 39, 1267-1271.
Russo, V. M. 2008. Plant density and nitrogen fertilizer rate on yield and nutrient content of onion developed from greenhouse-grown transplants. Hort Sci. 43(6): 1759-1764.
Saeey, M. 2011. Economical comparison of surface and drip irrigation for tomato cultivated under  polyetilen mulch in Jiroft district. Iranian J. Irrig. Res. 5(8): 89-98. (in Farsi)
Schrader, W. 2000. Using transplants in vegetable production. Available at:http:// anrcatalog.ucdavis.edu.
Soltani, Gh. 1990. Engineering Economics. Shiraz University Press. Shiraz. Iran. (in Farsi)
Taki, O. 2013. Development of a self-propelled transplanter for dense planting of bare-root onion seedlings.  Final Research Report.  Esfahan Agriculture Research Center. (in Farsi)
Taki, O. and Asadi, A. 2012. A creeper gearbox for MF-285 tractor.  Iran Patent.  No. 75789. (in Farsi)
Taki, O. and Asadi, A. 2014. Development of a semi-Automatic transplanter for dense planting of bare- root onion seedlings. J Agri. Eng. Res. 15(3): 67-80. (in Farsi)
Irrigation and Drainage Structures Engineering Research
Volume 16, Issue 1 - Serial Number 1
January 2016
Pages 79-94
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History
  • Receive Date: 03 May 2014
  • Revise Date: 06 July 2014
  • Accept Date: 10 January 2015
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