ILLUMINATION SCREENING AND UNIFORMITY SIMULATION OF HYDROPONIC LETTUCE IN ARTIFICIAL LIGHT PLANT FACTORY

DOI: https://doi.org/10.32845/msnau.2022.3.1
Keywords: LED plant light source; light formula; illumination uniformity; hydroponics; plant factory with artificial light; urban agriculture; smart agriculture

Abstract

With the development of LED plant lighting technology and its wide application in agricultural production, LED plant grow lights have become the mainstream light source used for plant lighting in plant factories with artificial light (PFALs). Artificial plant light source is different from natural light source, its biggest characteristic in light quality, light intensity, photo period and light form all can be accurately and intelligently regulated, ideally can continue to provide plants with light energy at the lowest cost, guarantee annual production and supply with high quality and efficient agricultural products, for the different living environment of people continue to supply the essential fresh plant products. Illumination and illumination uniformity have a significant impact on plant photosynthesis and growth, and are also the basis of the design of plant lighting system in PFALs. In this paper, taking the lettuce varieties planted in the field as the test materials and experimental objects, we design the illumination gradient test, simulate the illumination uniformity of LED forms with different arrangement by using the computer simulation method, and study the influence of different illumination and LED arrangement forms on the growth and biomass of hydroponic Lettuce in PFALs, so as to provide the best lighting solution for the industrialization and standardized production of lettuce in plant factories. The results of the study showed that: for hydroponic lettuce in PFAL’s lighting environment, the illumination uniformity of matrix LED light source is the best. The optimal lighting distance is between about 25cm and 30 cm from the lettuce. A red-blue light mixture ratio of 7:1 is the best light quality ratio for lettuce during seedling stage, and a red-blue light mixture ratio of 6:1 is the best light quality ratio in the growth period. The optimum light intensity is 400 2 µmol m s / ⋅ . The best daily illumination time is 16 h d/ , and the illumination time can be appropriately extended to achieve the purpose of harvesting lettuce in advance

References

1. Ares G., Birgit H. & Jaeger R. (2021). Consumer attitudes to vertical farming (indoor plant factory with artificial lighting) in China, Singapore, UK, and USA: A multi-method study. Food Research International, 110811.
2. Ding J.J. (2014). Effects of LED duty cycle on growth, yield, quality and photosynthetic characteristics of lettuce. Master's thesis, Northwest University of agriculture and forestry science and Technology.
3. He D.X. (2018). New trend of industrialization of artificial light plant factory in China. Chinese vegetables, (05): 1-8.
4. Huang L.C. (2019). Consumer Attitude, Concerns, and Brand Acceptance for the Vegetables Cultivated with Sustainable Plant Factory Production Systems. Sustainability, 11(18).
5. Huebbers W. and Buyel F. (2020). On the verge of the market – Plant factories for the automated and standardized production of biopharmaceuticals. Biotechnology Advances, 107681.
6. Jiang J., Mohagheghi A. & Moallem M. (2020). Energy-Efficient Supplemental LED Lighting Control for a Proof-ofConcept Greenhouse System. IEEE Transactions on Industrial Electronics, 67(4),3033-3042.
7. Kim S.J., Bok G., Lee G. & Park J. (2017). Growth Characteristics of Lettuce under Different Frequency of Pulse Lighting and RGB Ratio of LEDs. Protected horticulture and Plant Factory, 26(2).
8. Kozai T., Hayashi E. & Amagai Y. (2020). Plant factories with artificial lighting (PFALs) toward sustainable plant production. Acta Horticulturae, 251-260.
9. Kozai T. (2019). Towards sustainable plant factories with artificial lighting (PFALs) for achieving SDGs. International Journal of Agricultural and Biological Engineering, 12(5),28-37.
10. Lee K. (2018). Effects of LED Light Quality of Urban Agricultural Plant Factories on the Growth of Daughter Plants of ‘Seolhyang’ Strawberry. Journal of Environmental Science International, 27(10),821-829.
11. Li D.X., Shang S.H., Zhou Z.C., Bu Y.L., Shu Q.W. & Lan L.B. (2012). Effects of different light sources and illumination modes on lettuce growth in plant factories. Changjiang vegetable, 2012 (24): 50-52.
12. Liu W.K. and Liu Y.F. (2017). Construction and application of light formula of LED intelligent plant factory. China lighting appliance, (10): 1-3.
13. Liu W.K. and Yang Q.C. (2014). Led plant light quality biology and plant factory development. Science and technology Herald, 32 (10): 25-2.
14. Marondedze C., Liu X.Y., Huang S.H., Wong C., Zhou X., Pan X.T., Huiting A., Nuo X., Tian X.C. and Wong A. (2018). Towards a tailored indoor horticulture: a functional genomics guided phenotypic approach. Horticulture Research, 5(1).
15. Massa D., Kim H., & Mitchell A. (2008). Plant Productivity in Response to LED Lighting. HortScience, 43(7),1951-1956.
16. Mou S.T., Wang J.X., Xin X., Yang Z.C. & Wu Y.J. (2020). Effects of different pulsed light on growth, quality and photosynthetic characteristics of lettuce. China Agricultural Science and technology guide, 22 (05): 35-41.
17. Orsini F., Pennisi G., & Gianquinto G. (2020). Sustainable use of resources in plant factories with artificial lighting (PFALs). European Journal of Horticultural Science, 85(5),297-309.
18. Paucek I., Pennisi G., Pistillo A., Appolloni E. & Gianquinto G. (2020). Supplementary LED Interlighting Improves Yield and Precocity of Greenhouse Tomatoes in the Mediterranean. Agronomy, 10(7),1002.
19. Prikupets B., Boos G.V. George V. & Tarakanov I.G. (2019). Optimisation of Lighting Parameters of Irradiation in Light Culture of Lettuce Plants Using LED Emitters. Light & Engineering, 43-54.
20. Saito K., Ishigami Y. & Goto E. (2020). Evaluation of the Light Environment of a Plant Factory with Artificial Light by Using an Optical Simulation. Agronomy, 10(11),1663.
21. Tsuruyama J. and Shibuya T. (2018). Growth and Flowering Responses of Seed-propagated Strawberry Seedlings to Different Photoperiods in Controlled Environment Chambers. HortTechnology, 28(4),453-458.
22. Wang H.O. and Li G.A. (2004). Understanding lighting LED. China lighting appliance, 2004 (02): 2-4.
23. Wang M.M. and Wang X.J. (2015). Philips greenpower led tissue culture lamp was successfully applied to tissue culture and propagation of plantain. China Flower horticulture, (22): 2-3.
24. Wang X.X. (2017). Effects of LED frequency and duty cycle on growth and photosynthetic characteristics of lettuce. Master's thesis, Northwest University of agriculture and forestry science and Technology.
25. Wei H., Wang M. & Jeong R. (2020). Effect of Supplementary Lighting Duration on Growth and Activity of Antioxidant Enzymes in Grafted Watermelon Seedlings. Agronomy, 10(3),337.
26. Wu R.M., Tu D.W., Huang Z.H. & Zhao Q.J. (2009). Illumination uniformity design of LED lighting system. Optical technology, 2009,35 (01): 74-76.
27. Yan Z., He D.X., Niu G.H. & Qin Y.H. (2020). Growth, nutritional quality, and energy use efficiency in two lettuce cultivars as influenced by white plus red versus red plus blue LEDs. International Journal of Agricultural and Biological Engineering, 13(2),33-40.
28. Yang Q.C., Xu Z.G., Chen H.D. & Song C.B. (2011). Application principle and technical progress of LED light source in modern agriculture. China Agricultural Science and technology guide, 13 (05): 37-43.
29. Yang Q.C. (2014). Development strategy of plant factory. Science and technology Herald, 32 (10): 20-24.
30. Yuan F., Gao Q., Liu l.H. et al. (2021). Chen Jinxing Construction of crop cultivation microenvironment and digital platform technology in plant factory. Agriculture and technology, 41 (09): 5-8.
31. Zhu Z., Ying S.S., Hu H.J., Tong X.Y. & Zheng S.H. (2015). Study on illumination distribution and uniformity of LED plant light source array. Zhejiang Agricultural Journal, 27 (08): 1489-1493.
Published
2023-03-30
How to Cite
Xinfa, W., Zubko, V., Onychko, V., & Mingfu, Z. (2023). ILLUMINATION SCREENING AND UNIFORMITY SIMULATION OF HYDROPONIC LETTUCE IN ARTIFICIAL LIGHT PLANT FACTORY. Bulletin of Sumy National Agrarian University. The Series: Mechanization and Automation of Production Processes, (3 (49), 3-10. https://doi.org/10.32845/msnau.2022.3.1
Issue
No. 3 (49) (2022): Bulletin of Sumy National Agrarian University. The series: Mechanization and Automation of Production Processes
Section
Articles