Theoretically, aeroponic cultivation is easy to make plant roots in a better growth environment. In order to give better play to the theoretical advantages of aeroponic cultivation, further optimize the structure of the aeroponic cultivation system, and make the aeroponic cultivation system more scientific and reasonable, a barrel-shaped aeroponic cultivation system is designed. The aeroponic cultivation system is composed of a monitoring and control system, power equipment, nutrient solution storage, and treatment facility, nutrient solution supply pipelines, aeroponic cultivation barrels, and nutrient solution return pipelines. The cultivation system working principle and its technical requirements were analyzed, and its structure for meeting the requirements of large-scale production was determined. A performance test of the barrel-shaped aeroponic cultivation system using cultivated narrow leaved Chinese chives was conducted. The Chinese chives were cultivated to 6 beds of the cultivation barrel. The system supplied nutrient solution every 30 min for 2 min each time. After 5 weeks growth, the length, leaf width, and single weight of Chinese chive ranged from 293-362 mm, 4.1-6.7 mm, and 3.48-5.47 g, respectively, the average length, leaf width, and single weight of Chinese chive were 327 mm, 5.1 mm, and 4.24 g, respectively, and there were no significant differences in the length, leaf width, and single weight of Chinese chive on 6 beds by One-way ANOVA. The test results showed that all the Chinese chive in each bed of the cultivation barrel grew well and uniform, which indicated that the circulation process of nutrient solution supply and return in the system was normal, the process of nutrient solution atomization in the system was uniform, and the aeroponic cultivation system operated normally and stable and could be applied in production.
Keywords: aeroponic cultivation, soilless cultivation, facility agriculture, Chinese chive
DOI: 10.25165/j.ijabe.20221504.7508

Citation: Qi S H, Ma Y F, Zhang M, Yin B Q, Xu Z Y, Liu S G. Design and experiment of a barrel-shaped aeroponic cultivation system. Int J Agric & Biol Eng, 2022; 15(4): 90–94.

aeroponic cultivation, soilless cultivation, facility agriculture, Chinese chive

Reyes J L, Montoya R, Ledesma C, Ramirez R. Development of an aeroponic system for vegetable production. Acta Horticulturae, 2012; 947: 153–156.

Lakhiar I A, Gao J M, Syed T N, Chandio F A, Tunio M H, Ahmad F, et al. Overview of the aeroponic agriculture – an emerging technology for global food security. Inter J of Agric & Biol Eng, 2020; 13(1): 1–10.

Bao L, Wei Z Q, Wang Z L, Jin W L, He W S. Effects of different nutrient solution concentrations and spraying frenquency on the early growth of aeroponic potatoes. Molecular Plant Breeding, 2019; 17(9): 3030–3039.

Salazar J D R, Candelo-Becerra J E, Velasco F E H. Growing arugula plants using aeroponic culture with an automated irrigation system. Inter J Agric & Biol Eng, 2020; 13(3): 52–56.

Li Q S, Li X Q, Tang B, Gu M M. Growth responses and root characteristics of lettuce grown in aeroponics, hydroponics, and substrate culture. Horticulturae, 2018; 4(4): 35–43.

Giurgiu R M, Morar G, Dumitra A, Vlasceanu G, Dune A, Schroeder F G. A study of the cultivation of medicinal plants in hydroponic and aeroponic technologies in a protected environment. Acta Horticulturae, 2017; 1170: 671–678.

Ritter E, Angulo B, Riga P, Herran C, Relloso J, San Jose M. Comparison of hydroponic and aeroponic cultivation systems for the production of potato minitubers. Potato Research, 2001; 44(2): 127–135.

Lakhiar I A, Gao J M, Syed T N, Chandio F A, Buttar N A. Modern plant cultivation technologies in agriculture under controlled environment: A review on aeroponics. Journal of Plant Interactions, 2018; 13(1): 338–352.

Xu X L. Current situation and development trend of vegetable soilless cultivation in China. Agricultural Engineering, 2019; 9(10): 121–123. (in Chinese)

Liu S G, Ma Y F, Nan S J, Zhang M, Xu Z Y, Che Z Z, et al. Design of aerosol–culture production system in sunlight greenhouse. Research of Agricultural Modernization, 2017; 38(5): 893–899. (in Chinese)

Yu Y Y, Jia D D, Zhuang Z, Zhu C X, Liu A Q. Research progress of plant cultivated by aeroponic cultivation. Jiangsu Agricultural Sciences, 2019; 47(18): 38–42. (in Chinese)

Jamshidi A R, Moghaddam A G, Ghoraba F M. Simultaneous optimization of water usage efficiency and yield of cucumber planted in a columnar aeroponic system. International Journal of Horticultural Science and Technology, 2020; 7(4): 365–375.

Weathers P J, Zobel R W. Aeroponics for the culture of organisms, tissues and cells. Biotechnology Advances, 1992; 10(1): 93–115.

Christie C B, Nichols M A. Aeroponics – A production system and research tool. Acta Horticulture, 2004; 648: 185–190.

Thakur K, Partap M, Kumar D, Warghat A R. Enhancement of picrosides content in Picrorhiza kurroa Royle ex Benth mediated through nutrient feeding approach under aeroponic and hydroponic system. Industrial Crops and Products, 2019; 133: 160–167.

Wang S B, Li B H, Zhu R J, Yang B. Study on growing development of eight leaf vegetables with aeroponical culture in greenhouse. Southwest China Journal of Agricultural Sciences, 2015; 28(4): 1854–1856. (in Chinese)

El-Helaly M A, Darwish O S. Effect of culture system: aeroponic, hydroponic and sandy substrate on growth, yield and chemical compositions of lettuce. Plant Archives, 2019; 19(2): 2543–2550.

Lakhiar I A, Gao J, Xu X, Syed T N, Chandio F A, Jing Z, et al. Effects of various aeroponic atomizers (droplet sizes) on growth, polyphenol content, and antioxidant activity of leaf lettuce (Lactuca sativa L.). Transactions of the ASABE, 2019; 62(6): 1475–1487.

Kim G S, Lee S E, Noh H J, Kwon H, Lee S W, Kim S Y, et al. Effects of natural bioactive products on the growth and ginsenoside contents of Panax ginseng cultured in an aeroponic system. Journal of Ginseng Research, 2012; 36(4): 430–441.

Rykaczewska K. Field performance of potato minitubers produced in aeroponic culture. Plant Soil and Environment, 2016; 62(11): 522–526.

Buckseth T, Sharma A K, Pandey K K, Singh B P, Muthurajc R. Methods of pre-basic seed potato production with special reference to aeroponics—A review. Scientia Horticulturae, 2016; 204: 79–87.

Shokri S, Tadayon M R. Effect of different nutrient solutions on yield and potato minituber production under aeroponic and hydroponic cultures. Journal of Science and Technology of Greenhouse Culture, 2018; 8(4): 79–88.

Tokunaga H, Nguyen H A, Nguyen V D, Le H H, Nguyen T H, Nguyen H, et al. An efficient method of propagating cassava plants using aeroponic culture. Journal of Crop Improvement, 2020; 34(1): 64–83.

Kumari A, Baskaran P, Chukwujekwu J C, Baskaran P, Chukwujekwu J C, de Kock C A, et al. The changes in morphogenesis and bioactivity of Tetradenia riparia, mondia whitei and Cyanoptis speciosa by an aeroponic system. Industrial Crops and Products, 2016; 84: 199–204.

Lian C L, Lan J X, Wang L L, Yang J F, Chen S Q. Research progress in aeroponic culture and its application prospect in medicinal plants. Modern Chinese Medicine, 2020; 22(3): 461–465. (in Chinese)

Hayden A L. Aeroponic and hydroponic systems for medicinal herb, rhizome, and root crops. Hortscience, 2006; 41(3): 536–538.

Movahedi Z, Rostami M. Production of some medicinal plants in aeroponic system. Journal of Medicinal Plants and By–Products, 2020; 9(1): 91–99.

Zhou C J. Modern greenhouse engineering. Beijing, China: Chemical Industry Press, 2010; 25p. (in Chinese)

Ma C W. Design and construction of agricultural facilities. Beijing: China Agricultural Press, 2014; 29p. (in Chinese)

Qi D F, Ma Q. Study on diurnal variation characteristics of light intensity, temperature and humidity in solar greenhouse under different weather conditions. Northern Horticulture, 2013; 23: 55–57. (in Chinese)