Numerical investigation of greenhouse climate considering external environmental factors and crop position in Sfax central region of Tunisia

•The management of agriculture in greenhouses relies on precise control of the indoor climate, considering the impact of external factors such as temperature and solar radiation.•An experimental setup was conducted to develop a comprehensive three-dimensional Computational Fluid Dynamics (CFD) model...

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Bibliographic Details
Published in:Solar energy 2023-11, Vol.264, p.112032, Article 112032
Main Authors: Abid, Hasna, Ketata, Ahmed, Lajnef, Mariem, Chiboub, Hamza, Driss, Zied
Format: Article
Language:English
Subjects:
CFD
Climate
Crop position
Greenhouse
Solar radiation
Temperature
Tunisian Sfax central region
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Summary:•The management of agriculture in greenhouses relies on precise control of the indoor climate, considering the impact of external factors such as temperature and solar radiation.•An experimental setup was conducted to develop a comprehensive three-dimensional Computational Fluid Dynamics (CFD) model for studying the greenhouse climate, incorporating the influence of air, crops, and soil.•The numerical results indicate that external temperature and radiation significantly affect the distributions of indoor temperature, (DO) irradiation, and static pressure.•Robust correlations based on test data were established to accurately capture the changes caused by external factors.•The influence of crops design was investigated through a series of numerical simulations conducted with and without crops configurations.•The study provides valuable insights into the impact of external factors on greenhouse climates and emphasizes the importance of accurate modeling and control for optimal agricultural management. This paper presents a comprehensive study on the influence of external factors and the crop positioning on indoor environments in Sfax, a central region of Tunisia, during summer climate conditions. To achieve this, an experimental setup is implemented, and a numerical model was developed. The model incorporates air, crops, and soil components to analyze their individual and combined effects on the indoor environment. The numerical results were validated through a comparison with test data obtained from a greenhouse prototype, specifically concerning air velocity and temperature profiles. An optimization of the numerical model was performed considering turbulence and radiation models and grid independence analysis to ensure accurate simulations. Moreover, both with and without crops configurations as well as the impact of the crop position were investigated through a series of numerical simulations. Based on the numerical and experimental findings, the study establishes robust correlations to capture the variations resulting from these factors. The study reveals that external factors, such as ambient air temperature and solar radiation, play a crucial role in determining the temperature inside the greenhouse. The comparative study revealed an increase of less than 1% with the integration of crops in the greenhouse. The central position of the crop emerged as optimal, resulting in a slight temperature reduction of around 2 K compared to the left and right positi
ISSN:0038-092X
1471-1257
DOI:10.1016/j.solener.2023.112032