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Innovative Fabrication Methods for Agricultural Equipment: The Case Of A 3-D Printed Paddy Drum Seeder-cum-Fertilizer Applicator


Affiliations
1 Division of Agricultural Engineering, ICAR-Indian Agricultural Research Institute (IARI), New Delhi 110012, India
2 AICRP on Increased Utilization of Animal Energy with Enhanced System Efficiency, ICAR-Central Institute of Agricultural Engineering, Bhopal, Madhya Pradesh 462038, India
3 Division of Agricultural Engineering and Renewable Energy, ICAR- Central Arid Zone Research, Jodhpur, Rajasthan 342003, India
4 Division of Agricultural Engineering, ICAR- Indian Agricultural Research Institute (IARI), New Delhi 110012, India
5 Division of Agronomy, ICAR-IARI, New Delhi 110012, India

Rice is a vital staple for nearly half of the global population. It is sown through methods like transplanting and direct-seeded rice (DSR). However, DSR offers more benefits than transplanting methods. While DSR offers advantages such as reduced labour and environmental impact, the separate manual application of fertilizers poses a significant challenge. Innovative 3-D printing technology, also known as additive manufacturing, has sparked a transformative shift across multiple industries, facilitating the production of complex three-dimensional structures based on digital blueprints. Its recent application within the agricultural sector has demonstrated significant potential in the fabrication of vital components for farm machinery. Considering this, an attempt has been made to develop components of a four-row manual-operated paddy drum seeder-cum-fertilizer applicator using 3-D printing technology in the Farm Power and Soil Dynamics laboratory of the Division of Agricultural Engineering, ICAR-IARI, New Delhi. The paper is exploring the 3-D printing techniques used for fabricating a complex drum seeder, utilizing a 3-D printer with a bed size of 220×220×240 mm. The drum of the seeder is comprised of two truncated seed chambers and a central cylinder chamber for efficient seed and fertilizer application in two rows. The process of fabricating a drum through 3-D printer is followed by printing all 14 components separately, including square guides for the drive shaft, truncated conical and cylindrical chambers, hoppers, lids, and orifice covers for each chamber. The printing duration is ranged from 1 to 40 hours. The study is highlighted the significant advantages of 3-D printing technology in the fabrication of the drum seeder. 3-D printed four-row paddy drum-seeder-cum-fertilizer applicator has effectively addresses key challenges by integrating fertilizer application with the drum-seeding process.The cost of fabrication of 3-D printed drums has been found to Rs. 3290.4 which is 40% of the total cost of equipment. The cost of operation of a paddy drum seeder-cum-fertilizer applicator per hectare is found to be 2.55 times less than the earlier reported cost of operation with a four-row paddy drum seeder.

Keywords

3-D printing, Additive manufacturing, Direct seeded rice, Paddy drum seeder-cum-fertilizer applicator, Band placement of fertilizer
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  • Innovative Fabrication Methods for Agricultural Equipment: The Case Of A 3-D Printed Paddy Drum Seeder-cum-Fertilizer Applicator

Abstract Views: 41  | 

Authors

Narayanan Selvam Radhakrishnan
Division of Agricultural Engineering, ICAR-Indian Agricultural Research Institute (IARI), New Delhi 110012, India
Shiv Pratap Singh
AICRP on Increased Utilization of Animal Energy with Enhanced System Efficiency, ICAR-Central Institute of Agricultural Engineering, Bhopal, Madhya Pradesh 462038, India
Hira Lal Kushwaha
Division of Agricultural Engineering and Renewable Energy, ICAR- Central Arid Zone Research, Jodhpur, Rajasthan 342003, India
Adarsh Kumar
Division of Agricultural Engineering, ICAR- Indian Agricultural Research Institute (IARI), New Delhi 110012, India
Susheel Kumar Sarkar
Division of Agricultural Engineering and Renewable Energy, ICAR- Central Arid Zone Research, Jodhpur, Rajasthan 342003, India
Kapila Shekhawa
Division of Agronomy, ICAR-IARI, New Delhi 110012, India

Abstract


Rice is a vital staple for nearly half of the global population. It is sown through methods like transplanting and direct-seeded rice (DSR). However, DSR offers more benefits than transplanting methods. While DSR offers advantages such as reduced labour and environmental impact, the separate manual application of fertilizers poses a significant challenge. Innovative 3-D printing technology, also known as additive manufacturing, has sparked a transformative shift across multiple industries, facilitating the production of complex three-dimensional structures based on digital blueprints. Its recent application within the agricultural sector has demonstrated significant potential in the fabrication of vital components for farm machinery. Considering this, an attempt has been made to develop components of a four-row manual-operated paddy drum seeder-cum-fertilizer applicator using 3-D printing technology in the Farm Power and Soil Dynamics laboratory of the Division of Agricultural Engineering, ICAR-IARI, New Delhi. The paper is exploring the 3-D printing techniques used for fabricating a complex drum seeder, utilizing a 3-D printer with a bed size of 220×220×240 mm. The drum of the seeder is comprised of two truncated seed chambers and a central cylinder chamber for efficient seed and fertilizer application in two rows. The process of fabricating a drum through 3-D printer is followed by printing all 14 components separately, including square guides for the drive shaft, truncated conical and cylindrical chambers, hoppers, lids, and orifice covers for each chamber. The printing duration is ranged from 1 to 40 hours. The study is highlighted the significant advantages of 3-D printing technology in the fabrication of the drum seeder. 3-D printed four-row paddy drum-seeder-cum-fertilizer applicator has effectively addresses key challenges by integrating fertilizer application with the drum-seeding process.The cost of fabrication of 3-D printed drums has been found to Rs. 3290.4 which is 40% of the total cost of equipment. The cost of operation of a paddy drum seeder-cum-fertilizer applicator per hectare is found to be 2.55 times less than the earlier reported cost of operation with a four-row paddy drum seeder.

Keywords


3-D printing, Additive manufacturing, Direct seeded rice, Paddy drum seeder-cum-fertilizer applicator, Band placement of fertilizer