Abstract
Mechanical transplanters are adopted to reduce human drudgery in manual transplanting. Different types of manual and self-propelled paddy transplanters are commercially available. The human involvement is higher for operating a 2-wheel paddy transplanter operator has to walk 10-22 km behind the machine in a day in puddled field conditions under high temperature (38-440 C) and humid conditions (70-80% RH) in summer. Besides that, the operator has to walk within the 30 cm row width, which causes chafing between the thighs of an operator. To reduce the physical and physiological workload of an operator, an integrated control lever actuating mechanism with gear motors was developed to operate a 2-wheel paddy transplanter remotely. The inductive proximity sensors (SN04-N distance detector) were used to control the crank rotation position of the gear motors, motor drives (BTS 7960), and microcontroller (STM32F4) was used to connect with the auto-driver kit to control the motor mechanism and sensors. The auto-driver kit consisted of a variety of accessories, a physical programmable circuit board, and software, that runs on a PC, used to write and upload computer code as a simplified version of C++ to the physical board. Although the initial cost of the machine with the developed system has been increased up to 28%, but at the same time the effective field capacity has been increased from 0.158 ± 0.02 ha h-1 to 0.175 ± 0.04, resulting the area covered per day and per year has also increased up to 11%. With the development of remotely controlled system, the labor requirement has been reduced from 20± 1 to 13± 1 man h ha-1, which results reduction up to 40%. Moreover, the human fatigue in terms of physical and physiological work load involved while walking behind the transplanter has been eliminated at much extent. As compared to the existing walk-behind type paddy transplanter, the net profit with the developed system rise up to 18.50 to 26.61 % per year and a boost of 34.10 to 51.63% in benefit-cost ratio. Field evaluation of a developed remote-controlled system for a two-wheel rice transplanter would be viable, reducing fatigue among machine operators/farm workers while increasing work productivity and safety.
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