Working Speed Analysis of the Gear-Driven Dibbling Mechanism of a 2.6 kW Walking-Type Automatic Pepper Transplanter

The development of an automatic walking-type pepper transplanter could be effective in improving the mechanization rate in pepper cultivation, where the dibbling mechanism plays a vital role and determines planting performance and efficiency. The objective of this research was to determine a suitable working speed for a gear-driven dibbling mechanism appropriate for a pepper transplanter, while considering agronomic transplanting requirements. The proposed dibbling mechanism consisted of two dibbling hoppers that simultaneously collected free-falling seedlings from the supply mechanism and dibbled them into soil. To enable the smooth collection and plantation of pepper seedlings, analysis was carried out via a mathematical working trajectory model of the dibbling mechanism, virtual prototype simulation, and validation tests, using a physical prototype. In the mathematical model analysis and simulation, a 300 mm/s forward speed of the transplanter and a 60 rpm rotational speed of the dibbling mechanism were preferable in terms of seedling uprightness and low mulch film damage. During the field test, transplanting was conducted at a 40 mm planting depth, using different forward speed levels. Seedlings were freely supplied to the hopper from a distance of 80 mm, and the success rate for deposition was 96.79%. A forward speed of 300 mm/s with transplanting speed of 120 seedlings/min was preferable in terms of achieving a high degree of seedling uprightness (90 ± 3.26), a low rate of misplanting (8.19%), a low damage area on mulch film (2341.95 ± 2.89 mm2), high uniformity of planting depth (39.74 ± 0.48 mm), and low power consumption (40.91 ± 0.97 W).

[1]  Junzhi Yu,et al.  Determining the minimal mulch film damage caused by the up-film transplanter , 2018 .

[2]  Jiang-Tao Ji,et al.  Design of the up-film transplanter and kinematic analysis of its planting devices , 2013, Proceedings of the 2013 International Conference on Advanced Mechatronic Systems.

[3]  Santosh K. Pitla,et al.  Evaluation of the Accuracy of Machine Reported CAN Data for Engine Torque and Speed , 2018 .

[4]  Su-Hun Kim,et al.  Effect of biochar application on growth of Chinese cabbage (Brassica chinensis) , 2017 .

[6]  Gaohong Yu,et al.  Design and tests of a rotary plug seedling pick-up mechanism for vegetable automatic transplanter , 2020, International Journal of Agricultural and Biological Engineering.

[7]  Edoardo Greppi FAO (Food and Agriculture Organization of the United Nations) , 1981 .

[8]  Quan Wang,et al.  Structure Design of Manipulator for Pot Seedling Transplanter and Simulation Analysis , 2014 .

[9]  T. Kang Identification of undeclared ingredients in red pepper products sold on the South Korea commercial market using real-time PCR methods , 2018, Food Control.

[10]  L. N. Shaw,et al.  A High-Speed Dibbling Transplanter , 1987 .

[11]  Pramod Chandra Dihingia,et al.  Development of a Hopper-Type Planting Device for a Walk-Behind Hand-Tractor-Powered Vegetable Transplanter , 2016 .

[12]  Hifjur Raheman,et al.  Development of a walk-behind type hand tractor powered vegetable transplanter for paper pot seedlings , 2011 .

[13]  S H Park,et al.  Development of Rotary Type Transplanting Device for Vegetable Transplanter , 2005 .

[14]  Jiangtao Ji,et al.  Development of single row automatic transplanting device for potted vegetable seedlings , 2018 .

[15]  Chung-Keun Lee,et al.  Development of a Mechanical Harvesting System for Red Pepper(I) - Surveys on Conventional Pepper Cultivation and Mechanization of Pepper Harvesting - , 2010 .

[16]  Tong Zhou,et al.  Development and Field Test of an Autonomous Strawberry Plug Seeding Transplanter for Use in Elevated Cultivation , 2019, Applied Engineering in Agriculture.

[17]  Wang Yujie,et al.  Optimized design and experiment of a fully automated potted cotton seedling transplanting mechanism , 2020, International Journal of Agricultural and Biological Engineering.

[18]  Ju-Seok Nam,et al.  Measurement of Mechanical and Physical Properties of Pepper for Particle Behavior Analysis , 2018 .

[19]  Shijun Sun,et al.  Assessing the effects of plant density and plastic film mulch on maize evaporation and transpiration using dual crop coefficient approach , 2019, Agricultural Water Management.

[20]  Abhijit Khadatkar,et al.  Automation in Transplanting:A Smart Way of Vegetable Cultivation , 2018, Current Science.

[21]  Jiangtao Ji,et al.  Design and test of 2ZLX-2 transplanting machine for oil peony , 2020, International Journal of Agricultural and Biological Engineering.

[22]  I. Ahmad,et al.  Plastic film mulching stimulates soil wet-dry alternation and stomatal behavior to improve maize yield and resource use efficiency in a semi-arid region , 2019, Field Crops Research.

[23]  Mohammod Ali,et al.  Kinematic Analysis of a Clamp-Type Picking Device for an Automatic Pepper Transplanter , 2020 .

[24]  Hifjur Raheman,et al.  Vegetable Transplanters for Use in Developing Countries—A Review , 2008 .

[25]  Md Zafar Iqbal,et al.  Analysis of Overturning and Vibration during Field Operation of a Tractor-Mounted 4-Row Radish Collector toward Ensuring User Safety , 2020, Machines.

[26]  Ajit K. Srivastava,et al.  Engineering Principles of Agricultural Machines , 1993 .

[27]  Zhao Hongzheng,et al.  Kinematic analysis and experiment of planetary five-bar planting mechanism for zero-speed transplanting on mulch film , 2016 .

[28]  Shan Yiyin,et al.  Theoretical analysis and development of a mechanism with punching device for transplanting potted vegetable seedlings , 2020, International Journal of Agricultural and Biological Engineering.

[29]  Konosuke Tsuga,et al.  Development of fully automatic vegetable transplanter. , 2000 .

[30]  P. Kim,et al.  Nitrous oxide emissions from soils amended by cover-crops and under plastic film mulching: Fluxes, emission factors and yield-scaled emissions , 2017 .

[31]  Mao Hanping,et al.  Development of a riding-type fully automatic transplanter for vegetable plug seedlings , 2019, Spanish Journal of Agricultural Research.

[32]  Manes,et al.  Feasibility of mechanical transplanter for paddy transplanting in Punjab , 2014 .

[33]  R. L. Parish,et al.  Current Developments in Seeders and Transplanters for Vegetable Crops , 2005 .