Development and Stability Analysis of a Self-propelled High Clearance Multi-utility Vehicle
DOI:
https://doi.org/10.52151/jae2022591.1762Keywords:
Centre of gravity, point manipulation method, self-propelled, stability, weight moment methodAbstract
A self-propelled hydraulically actuated vehicle was developed for field crops of up to 2.0 m in height to carry out different operations like spraying, weeding, harvesting. The vehicle has provision for variable/adjustable ground clearance and track width to suit different spacing and heights of horticultural crops. Gradability, torque, and power required for the vehicle were calculated based on the dimensions of the selected bias ply traction tyre. The centre of gravity of the vehicle was calculated by the weight moment method. Microsoft Excel add-in was used to create a point manipulation programme, and the positions of the standard components were determined through an iterative process. The static load over the rear wheel and front wheel was kept at 60% and 40%, respectively, for design purposes. Analysis of chassis mechanics was done to find out weight transfer and impending stability on level ground as well as longitudinal and lateral slope. In longitudinal slope, the developed vehicle was found to be stable up to 45.19° and 20.68° under static and dynamic conditions, respectively; whereas in lateral slope, the vehicle was stable up to 39.08° and 22.10° under static and dynamic conditions, respectively. The developed vehicle was tested for weeding and spraying of okra and maize crops with an average height of 1.1 m to 1.5 m. The field capacity for the spraying and weeding operations was 1.9 ha.h-1 and 0.16 ha.h-1, respectively. The cost of operation for spraying and weeding was 400 ?.ha-1 and 1,500 ?.ha-1, respectively. Weeding efficiency and plant damage of the weeder were 92.58% and 1.55%, respectively.
References
Anon. 1989. Cranes - Design Principle for Loads and Load Combinations. Bureau of Indian Standards IS/ ISO 8686-1: Part-1, 1-12
Anon. 2017. Report of National Round Table Conference on Farm Mechanization. Indian Council of Food and Agriculture, 31 January.
Balachandar G. 2022. Annual tractor production crosses 1million, exports surpass 1 lakh for the 1st time in 2021. The Hindu Business line, Chennai, https://www.thehindubusinessline.com/news. 9th January 2022.
Khurmi R S; Gupta J K. 2020. Theory of Machine. S. Chand Publishing, India, 14th edition, Chapter 19, 708-751.
Liljedahl J B; Turnquist P K; Smith D W. 2004. Tractors and Their Power Units. Wiley and Sons, New York, 247-248.
Macmillan R H. 2002. The Mechanics of Tractor - Implement Performance: Theory and Worked Examples. University of Melbourne, Australia. Printed from: http://www.eprints.unimelb.edu.au.
Mahal J S; Garg L K; Sharma V K; Dixit A K. 2007. Development of high clearance power sprayer for cotton. J. Agric. Eng., 44(3), 92-96.
Safarzadeh D; Sulaiman S; Abdul A F; Ahmad D B; Majzoobi G H. 2011. The design process of a selfpropelled floor crane. J. Terramec., 48, 157-168.
Segerlind L J. 2010. Design of a Floor Crane. Designing Structural Components for Machine, ASABE, St. Joseph, Michigan, Chapter 13, 387-415.
Singh S P; Singh S. 2021. Farm power availability and its perspective in Indian agriculture. RASSA J. Sci. Soc., 3(2), 114-126.
Verma H C. 2020. Concepts of Physics. Bharati Bhawan, vol.1, Chapter 7, 127-151.
Wismer R D; Luth H J. 1974. Off-road traction prediction for wheeled vehicles. Trans. ASAE, 17(1), 8-10.
Wong J Y. 1993. Theory of Ground Vehicles. WileyInterscience, London, 2nd edition, 26.
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