현장농수산연구지 (Journal of Practical Agriculture & Fisheries Research)

국립한국농수산대학교 교육개발센터 (Korea National University of Agriculture and Fisheries)
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행거식 순환형 딸기 재배시스템 개발

Development of Hanging Type Circular-patterned System for Strawberry Cultivation

  • 안세웅 (국립한국농수산대학교 원예학부) ;
  • 김동억 (국립한국농수산대학교 교양학부) ;
  • 홍순중 (국립한국농수산대학교 교양학부) ;
  • 강동현 (국립한국농수산대학교 교양학부)
  • Sewoong An (Department of Horticulture, Korea National University of Agriculture and Fisheries) ;
  • Dong Eok Kim (Department of Liberal Arts, Korea National University of Agriculture and Fisheries) ;
  • Soonjung Hong (Department of Liberal Arts, Korea National University of Agriculture and Fisheries) ;
  • Dong Hyeon Kang (Department of Liberal Arts, Korea National University of Agriculture and Fisheries)
  • 투고 : 2024.04.02
  • 심사 : 2024.06.24
  • 발행 : 2024.06.30
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초록

This study was conducted to develop the hanging type circular-patterned system that at maximizing the spatial efficiency of strawberry cultivation to increase yields, while also reducing labor and improving energy efficiency. The system consists of a cultivation bed units, longitudinal moving device, bed lifting device, front and rear transfer devices, lateral transfer device, nutrient supply device, and control unit. Performance testing revealed that the operational motor for longitudinal movement should have a torque of at least 0.1Nm based on the design weight and traction force of the cultivation bed unit. The power consumption required to move one cycle was calculated to be approximately 149Wh when performing harvesting or maintenance tasks for all 10 cultivation beds. Vibration angles measured during bed movement showed that the lateral transfer resulted in a roll angle ranging from -0.62° to 0.68° and a pitch angle ranging from -3.79° to 5.26°. For longitudinal transfer, the roll angle ranged from -3.37° to 3.36°, and the pitch angle ranged from -0.45° to 0.49°.

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참고문헌

  1. Chang YS, Gap SH, and Kim DE. 2005. Development of a chain conveyor type row- spacing system for plant factory. Journal of Bio-Environment Control 14(1):7-14. 
  2. Hayashi S, Saito S, Iwasaki Y, Yamamoto S, Nagoya T, and Kano K. 2011. Development of circulating-type movable bench system for strawberry cultivation. Japan Agricultural Research Quarterly 45(3): 285-293.  https://doi.org/10.6090/jarq.45.285
  3. Ikeda H. 2006. Introduction and problems of a table-top cultivation for strawberry. Agriculture and Horticulture 61(9):14-16. 
  4. Iwasaki Y, Yoshida C, Urushiyama Y, Yoshida H, Saito S, Yamamoto S, Hayashi S, Ikeda H, and Ikeda T. 2012. Investigation of row spacing and nutrient solution supply method for high plant density production of strawberry using movable bench. Horticultural Research 11(1):49-57.  https://doi.org/10.2503/hrj.11.49
  5. Jun HJ, Byun MS, Liu SS, Jeon EH, and Lee YB. 2013. Effect of nutrient solution strength on growth, fruit quality and yield of strawberry 'Maehyang' in hydroponics. Korean Journal Of Horticultural Science & Technology 31(2):173-178.  https://doi.org/10.7235/hort.2013.12182
  6. Kang DH, Lee SY, Kim YJ, Kim JG, Choi HG, and Min YB. 2013. Development of circulatingtype cultivating system for strawberry cultivation. Journal of Agriculture & Life Science 47(6):311- 319.  https://doi.org/10.14397/jals.2013.47.6.311
  7. Kang DH, Lee SY, Park MJ, Choi HG, and Paek Y. 2016. Study of strawberry high-density cultivating system using movable bed. J. Korean Soc. Mech. Technol 18(1):121-127.  https://doi.org/10.17958/ksmt.18.1.201602.121
  8. Kang EI, Hu JT, Li Y, and Jeong BR. 2020. Growth, Productivity, and quality of strawberry as affected by propagation method and cultivation system. Protected Horticulture And Plant Factory 29(4):326-336.  https://doi.org/10.12791/KSBEC.2020.29.4.326
  9. Koichi O. 2021. Strawberry harveting robot. Journal of the Robotics Society of Japan 39(10); 888-891.  https://doi.org/10.7210/jrsj.39.888
  10. Tsubota S., Teshima T, Yamamoto S, Kobayashi T, Nakayama N, Loan N, and Hayashi S. 2019. Measurement of sugar content by stationary strawberry-harvesting robot. J.SHITA 31(1):31-41.  https://doi.org/10.2525/shita.31.31
  11. Yoshida H, Yamamoto S, Hayashhi S, Iwasaki Y, and Urushiyama Y. 2008. Development of a movable bench system for high-density cultivation of strawberries. Journal of JSAM 70(4):98-106. 
  12. Yu IH, Jeong HJ, Cheong JW, Nam YI, Lee SY, Cho MW, Kim TY, Choi GL, and Roh MY. 2005. Devlopment of standard bench models for labor-saving production of strawberry seedling. Korean Journal of Horticultural Science & Technology 23(SUPPL. I): 40.