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Abstract
In a commercialized, fully artificial plant factory, artificial luminaire is arranged in a unified way using a general illumination theory, an actual measurement, or an empirical methodology. However, with these methods, lightings are implemented without considering specific optical characteristics of lighting or material characteristics of each component that constructs a cultivation system, resulting in an amount of light that becomes irregular. The amount of lighting is closely related with the growth and quality of crops, and the deviation between points where cultivated crops are located causes quality difference in the produced crops, thus impairing the economic feasibility of a plant factory. In this regard, a simulation to figure out an optimum lighting layout was performed. Arrangements based on the spectrum distribution of light source and reflector materials were implemented to ascertain the distance between lighting and height of lighting and gather information in the pre-treatment process to improve the uniformity of light in the plant cultivation system. Improvement of around 15% in light uniformity is achieved compared with the existing system after the simulation is carried out. This result would reduce the deviation in crop growth to make uniform quality crop production possible.
Keywords
high-quality crop
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light uniformity improvement
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optimal lighting layout
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fully artificial plant factory
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Relux simulation
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Lee Hwa-Soo, Kwon Sook-Youn, Lim Jae-Hyun.
Improvement of light uniformity by lighting arrangement for standardized crop production.
Journal of Central South University, 2014, 21(11): 4311-4319 DOI:10.1007/s11771-014-2430-5
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