Journal of Agricultural Machinery

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Development and Evaluation of an Onion Harvester Machine with Excrescence Axes

Document Type : Research Article

Authors

Department of Mechanical Engineering of Biosystems, Shahid Bahonar University of Kerman, Kerman, Iran

Abstract

Introduction
It is common to use rod weeders for onion harvesting according to their prevention of root blocking in front of the machine and separation of onion bulbs from soil by shaking. Chesson et al., (1977), used a rod weeder for manufacturing an onion harvester. This machine had a rectangular rotor axis with 25mm×25mm cross section. The rotor power was provided by a hydro-motor. An investigation into onion losses during the harvesting operation showed that the majority of crop damages have been occurred due to the collision of rods with onion bulbs. Therefore, the objective of this study is to design and evaluate an onion harvester based on rod weeders with the capability of crop harvesting with minimum damage.

Materials and Methods
The main components of the examined onion harvester are chassis, furrower, and power transmission system and excrescence axes. Rectangular 100mm×100mm and 40mm×80mm profiles with 4mm profile thickness are used to fabricate the chassis. The furrowers were installed on each side of the chassis as the first parts of the harvester that comes into contact with the soil. Power transmission system provided rotation of two axes from both sides of the machine due to the lack of space for working of two chains on the one side. Therefore, a gearbox having one input shaft and two output shafts was selected for the machine. The gearbox output shafts turn the rotors with a reduction ratio of 1 to 3.5. The rotary motion of the excrescence axes cuts and moves the soil located under the onions bulbs upward and finally the onion bulbs are placed on the soil surface. Therefore, excrescence axes can be considered as the main part of the onion harvester. The excrescence shape of the axes were created by star wheels. Star wheels had a hole with a square section in center (30mm×30mm), for installing them on their shaft. Choosing this kind of the connection, dose not let star wheels to move freely. Also to limit the lateral movement of the star wheels on axis, metallic spacers were used between the adjacent pairs of them. To evaluate the machine performance three variable factors were defined: working depth (20 and 26 cm), forward speed (3, 4.5 and 6 km h-1) and rotational speed of the excrescence axes (150, 220 and 290 rpm). The conducted experiments were analyzed in a complete randomized design with three replications.

Results and Discussion
The analysis of variance showed that the working depth and forward velocity of axis had significant effect (in 5% level) on the success rate of onion harvester. Also the interaction between depth and forward velocity and the interaction between rotational speed of axes and forward speed were significant. The interaction between depth and rotational speed of axes and the interaction between depth, rotational speed of axes and forward speed were not significant. Evaluation of the interaction between depth and forward velocity showed that the most success rate of onion harvesting was in 20 cm depth and forward velocity equal to 3 and 4.5 km h-1. The least success was gained in 26 cm depth with 4.5 and 6 km h-1 forward speed. Evaluation of the interaction between rotational speed of axes and forward speed showed that the most success in the onion harvesting was occurred with a machine having 3 km h-1 forward velocity and 150 rpm rotational speed and also 4.5 km h-1 forward velocity and 220 rpm rotational speed.

Conclusion
The success rate of the onion harvesting decreased by increasing the working depth of the machine and axes distance to the onion bulbs. Also with excessive forward velocity the success rate of onion harvesting decreased because of difficulties in controlling the tractor guidance in straight line. The best performance of this onion harvesting machine was in 20 cm depth, 4.5 km h-1 forward velocity and 220 rpm axes rotational speed. Adjusting the machine working parameters according to these values, the ratio of the linear speed of the star wheel tips to the forward velocity of the machine (kinematic index) was equal to 0.82.

Keywords

Main Subjects

References
1. Anonymous. 1984. Evaluation Report. Tested at Humboldt. Prairie Agricultural Machinery Institute. ISSN 0383-3445. Available from: http://www.worldcat.org/title/pami-evaluation-report/oclc/5791059.
2. Balls, R. C. 1985. Horticultural Engineering Technology: Fixed Equipment and Buildings. Macmillan Pub.LTD.
3. Bernacki, H., J. Haman and C. Z. Kanafojski. 1972. Agricultural machines, theory and construction. US department of Agriculture and national science foundation, Washington, D.C.
4. Chesson, J., H. Johnson Jr, C. Brooks, R. Curley, P. Burkner, and R. Perkins. 1977. Mechanical harvesting investigations for fresh market onions. Transactions of the ASAE 21 (5): 0838-0842.
5. Harrison, H. P., and X. Bai. 1990. Rod weeder soil reaction force for different rod shapes and speeds. Transactions of the ASAE 33 (5): 1445-1448.
6. Heidari Soltanabadi, M., O. Taki, and Sh. Abdolahpur. 2013. Effect of kinematic indeces and rod shape on performance of an onion rod digger. Journal of Agricultural Engineering Research 14 (3): 15-28. (In Farsi).
7. Jafari, K., H. Baradaran, R. Ahmadi, and M. Shekari. 2015. Study and Simulation of the Effective Factors on Soil Compaction by Tractors Wheels Using the Finite Element Method. Journal of Computational Applied Mechanics 46 (2): 107-115.
8. Klenin, N. I., I. F. Popov, and V. A. Sakun. 1986. Agricultural Machines: Theory of Operation, Computation of Controlling Parameters and the Conditions of Operation. Russian Translation. Series 31.
9. Laryushin, N., and A. Laryushin. 2009. Energy-Saving onion harvesting technology. Russian Agricultural Sciences 35 (1): 66-67.
10. Mayberri, K. S., and H. Meister. 2003. Sample cost to establish and produce market onions. U. C. Cooperative Extension. University of California and the United States Department of Agricultural Cooperating.
11. Mozafari, M., and K. Kazemeinkhah. 2000. Design, Development and evaluation of suitable onion harvester for small farms (laboratory scale). Agricultural Engineering Research Institute. (In Farsi).
12. Rusinek, T., J. Mishanec, and J. Lorbeer. 2008. Analysis of onion management practices as they relate to levels of aspergillus niger (black mold) and development of IPM scouting protocols for blackmold.
13. Shigley, J. E. 2011. Shigley's mechanical engineering design. Tata McGraw-Hill Education.
14. Srivastava, A., C. E. Goering, and R. P. Rohrbach. 1993. Engineering principles of agricultural machines. American Society of Agricultural Engineers. Michigan. USA.
15. Taki, O. 2011. Development of a front-mounted rod-digger for harvesting non-row Basis onions. Annual Research Report. Agricultural Engineering Research Institute. Agriculture and Natural Resources Research Center of Isfahan. (In Farsi).
16. Zeinali, A., A. Farzad, and M. H. AghKhani. 2014. Design, implementation and evaluation of a torque transducer with ability of real-time torque monitoring. Journal of Agricultural Machinery 4 (1): 194-205. (In Farsi).
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Journal of Agricultural Machinery
Volume 8, Issue 2 - Serial Number 16
Fall and Winter
2018
Pages 249-262
Files
History
  • Receive Date: 19 February 2017
  • Revise Date: 22 May 2017
  • Accept Date: 11 July 2017
  • First Publish Date: 23 September 2018
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