This study proposed a comprehensive evaluation system to incorporate the contribution of both numerical simulation and statistical decision theory in ventilation performance assessment. A high-resolution model based on the finite volume approach was established to analyze the influence of rotation angles (i.e., side vent flip angle and roof vent flip angle) of the rack-and-pinion ventilated structure on the greenhouse microclimate. The water circulating system and tomato seeding canopies were considered. Heat removal efficiency and mean age of air were employed as quantitative attributes to reflect the internal thermal environment and the airflow organization in the sliding cover solar greenhouse. The simulation model was verified with the temperature profile measured and the average relative error was 1.74%. The results demonstrate that the rotating angles of ventilation schemes have a substantial impact on the microclimate and inhomogeneity of the tomato seeding canopies. The results suggest the average velocity and its inhomogeneity are the crucial predictors, and their entropy weight values are 0.231 and 0.218, respectively. The relative degree of membership of the side vent flip angle of 45° is 36% and 97% higher than that of the side vent flip angle of 35° and the side vent flip angle of 25°, respectively. This study can provide a reference to evaluate the ventilated strategies of the sliding cover solar greenhouse for the regional and central government.
Keywords: sliding cover solar greenhouse, natural ventilation, CFD simulation, entropy weight, comprehensive evaluation
DOI: 10.25165/j.ijabe.20211406.6793

Citation: Li H, Ji D, Hu X, Xie T, Song W T, Tian S B. Comprehensive evaluation of combining CFD simulation and entropy weight to predict natural ventilation strategy in a sliding cover solar greenhouse. Int J Agric & Biol Eng, 2021; 14(6): 213–221.

sliding cover solar greenhouse, natural ventilation, CFD simulation, entropy weight, comprehensive evaluation

Wang J, Li S, Guo S, Ma C, Wang J, Jin S. Simulation and optimization of solar greenhouses in Northern Jiangsu Province of China. Energy and Buildings, 2014; 78: 143–152.

He X, Wang J, Guo S, Zhang J, Wei B, Sun J, et al. Ventilation optimization of solar greenhouse with removable back walls based on CFD. Computers and Electronics in Agriculture, 2018; 149: 16–25.

Cuce E, Harjunowibowo D, Cuce P M. Renewable and sustainable energy saving strategies for greenhouse systems: A comprehensive review.

Renewable Sustainable Energy Reviews, 2016; 64: 34–59.

Choab N, Allouhi A, El Maakoul A, Kousksou T, Saadeddine S, Jamil A. Review on greenhouse microclimate and application: Design parameters, thermal modeling and simulation, climate controlling technologies. Solar Energy, 2019; 191: 109–137.

Shamshiri R R, Kalantari F, Ting K C, Thorp K R, Hameed I A, Weltzien C, et al. Advances in greenhouse automation and controlled environment agriculture: A transition to plant factories and urban agriculture. Int J Agric Biol Eng, 2018; 11(1): 1–22.

Saberian A, Sajadiye S M. The effect of dynamic solar heat load on the greenhouse microclimate using CFD simulation. Renewable Energy, 2019; 138: 722–737.

Chen J, Ma Y, Pang Z. A mathematical model of global solar radiation to select the optimal shape and orientation of the greenhouses in southern China. Solar Energy, 2020; 205: 380–389.

Zhang X, Lyu J, Dawuda M M, Xie J, Yu J, Gan Y, et al. Innovative passive heat-storage walls improve thermal performance and energy efficiency in Chinese solar greenhouses for non-arable lands. Solar Energy, 2019; 190: 561–575.

Cao S J, Ren C. Ventilation control strategy using low-dimensional linear ventilation models and artificial neural network. Building and Environment, 2018; 144: 316–333.

Cao K, Xu H, Zhang R, Xu D, Yan L, Sun Y, et al. Renewable and sustainable strategies for improving the thermal environment of Chinese solar greenhouses. Energy and Buildings, 2019; 202: 109414. doi: 10.1016/j.enbuild.2019.109414.

Boulard T, Roy J C, Pouillard J B, Fatnassi H, Grisey A. Modelling of micrometeorology, canopy transpiration and photosynthesis in a closed greenhouse using computational fluid dynamics. Biosystems Engineering, 2017; 158: 110–133.

Sethi V P, Sumathy K, Lee C, Pal D S. Thermal modeling aspects of solar greenhouse microclimate control: A review on heating technologies. Solar Energy, 2013; 96: 56–82.

Li A, Huang L, Zhang T. Field test and analysis of microclimate in naturally ventilated single-sloped greenhouses. Energy and Buildings, 2017; 138: 479–489.

Mistriotis A, Bot G P A, Picuno P, Scarascia-Mugnozza G. Analysis of the efficiency of greenhouse ventilation using computational fluid dynamics. Agricicultural and Forest Meteorology, 1997; 85(3–4): 217–228.

Kitaya Y, Tsuruyama J, Shibuya T, Yoshida M, Kiyota M. Effects of air current speed on gas exchange in plant leaves and plant canopies. Advances in Space Research, 2003; 31(1): 177–182.

Saberian A, Sajadiye S M. Assessing the variable performance of fan-and-pad cooling in a subtropical desert greenhouse. Applied Thermal Engineering, 2020; 179: 115672. doi: 10.1016/j.applthermaleng.2020.115672.

Ghoulem M, El Moueddeb K, Nehdi E, Zhong F, Calautit J. Analysis of passive downdraught evaporative cooling windcatcher for greenhouses in hot climatic conditions: Parametric study and impact of neighbouring structures. Biosystems Engineering, 2020; 197: 105–121.

Lu W, Zhang Y, Fang H, Ke X, Yang Q. Modelling and experimental verification of the thermal performance of an active solar heat storage-release system in a Chinese solar greenhouse. Biosystems Engineering, 2017; 160: 12–24.

Teitel M, Wenger E. Air exchange and ventilation efficiencies of a monospan greenhouse with one inflow and one outflow through longitudinal side openings. Biosystems Engineering, 2014; 119: 98–107.

Flores-Velazquez J, Montero J I, Baeza E J, Lopez J C. Mechanical and natural ventilation systems in a greenhouse designed using computational fluid dynamics. Int J Agric Biol Eng, 2014; 7(1): 1–16.

Benni S, Tassinari P, Bonora F, Barbaresi A, Torreggiani D. Efficacy of greenhouse natural ventilation: Environmental monitoring and CFD simulations of a study case. Energy and Buildings, 2016;125: 276–286.

Ould Khaoua S A, Bournet P E, Migeon C, Boulard T, Chassériaux G. Analysis of greenhouse ventilation efficiency based on computational fluid dynamics. Biosystems Engineering, 2006; 95(1): 83–98.

Villagrán E A, Baeza Romero E J, Bojacá C R. Transient CFD analysis of the natural ventilation of three types of greenhouses used for agricultural production in a tropical mountain climate. Biosystems Engineering, 2019; 188: 288–304.

Campen J B, Bot G P A. Determination of greenhouse-specific aspects of ventilation using three-dimensional computational fluid dynamics.

Biosystems Engineering, 2003; 84(1): 69–77.

Bournet P E, Ould Khaoua S A, Boulard T. Numerical prediction of the effect of vent arrangements on the ventilation and energy transfer in a multi-span glasshouse using a bi-band radiation model. Biosystems Engineering, 2007; 98(2): 224–234.

Chen J L, Xu F, Tan D P, Shen Z, Zhang L B, Ai Q L. A control method for agricultural greenhouses heating based on computational fluid dynamics and energy prediction model. Applied Energy, 2015;141: 106–118.

Tong G, Christopher D M, Li B. Numerical modelling of temperature variations in a Chinese solar greenhouse. Computers and Electronics in Agriculture, 2009; 68(1): 129–139.

Norton T, Sun D W, Grant J, Fallon R, Dodd V. Applications of computational fluid dynamics (CFD) in the modelling and design of ventilation systems in the agricultural industry: A review. Bioresource Technology, 2007; 98(12): 2386–2414.

Bournet P-E, Boulard T. Effect of ventilator configuration on the distributed climate of greenhouses: A review of experimental and CFD studies. Computers Electronics in Agriculture, 2010; 74(2): 195–217.

Delgado A, Romero I. Environmental conflict analysis using an integrated grey clustering and entropy-weight method: A case study of a mining project in Peru. Environmental Modelling & Software, 2016; 77: 108–121.

Lee S Y, Lee I B, Yeo U H, Kim R W, Kim J G. Optimal sensor placement for monitoring and controlling greenhouse internal environments. Biosystems Engineering, 2019; 188: 190–206.

Feng G Z, Lei S Y, Guo Y J, Meng B, Jiang Q F. Optimization and evaluation of ventilation mode in marine data center based on AHP-entropy weight. Entropy, 2019; 21(8): 796. doi: 10.3390/e21080796.

Ziapour B M, Dehnavi R. A numerical study of the arc-roof and the one-sided roof enclosures based on the entropy generation minimization. Computers & Mathematics with Applications, 2012; 64(6): 1636–1648.

Chen S K, Leng Y, Mao B H, Liu S. Integrated weight-based multi-criteria evaluation on transfer in large transport terminals: A case study of the Beijing South Railway Station. Transportation Research Part A: Policy and Practice, 2014; 66: 13–26.

Zhang X, Wang H, Zou Z, Wang S. CFD and weighted entropy based simulation and optimisation of Chinese Solar Greenhouse temperature distribution. Biosystems Engineering, 2016; 142: 12–26.

Li H, Li Y M, Yue X, Liu X G, Tian S B, Li T L. Evaluation of airflow pattern and thermal behavior of the arched greenhouses with designed roof ventilation scenarios using CFD simulation. PLoS One, 2020; 15(9): e0239851. doi: 10.1371/journal.pone.0239851.

Tong X, Sun Z, Sigrimis N, Li T. Energy sustainability performance of a sliding cover solar greenhouse: Solar energy capture aspects. Biosystems Engineering, 2018; 176: 88–102.

Zhang G, Fu Z, Yang M, Liu X, Dong Y, Li X. Nonlinear simulation for coupling modeling of air humidity and vent opening in Chinese solar greenhouse based on CFD. Computers and Electronics in Agriculture, 2019; 162: 337–347.

Akrami M, Javadi A A, Hassanein M J, Farmani R, Dibaj M, Tabor GR, et al. Study of the effects of vent configuration on mono-span greenhouse ventilation using computational fluid dynamics. Sustainability, 2020;12(3): 986. doi: 10.3390/su12030986.

Pakari A, Ghani S. Airflow assessment in a naturally ventilated greenhouse equipped with wind towers: Numerical simulation and wind tunnel experiments. Energy and Buildings, 2019; 199: 1–11.

Qi D, Li A G, Li S X, Zhao C Y. Comparative analysis of earth to air heat exchanger configurations based on uniformity and thermal performance. Applied Thermal Engineering, 2021; 183(Part1): 116152. doi: 10.1016/j.applthermaleng.2020.116152.

Liu X, Li H, Li Y M, Yue X, Tian S B, Li T L. Effect of internal surface structure of the north wall on Chinese solar greenhouse thermal microclimate based on computational fluid dynamics. PLos One, 2020;15(4): e0231316. doi: 10.1371/journal.pone.0231316.

Tong G, Christopher D M, Zhang G. New insights on span selection for Chinese solar greenhouses using CFD analyses. Computers Electronics in Agriculture, 2018; 149: 3–15.

van Hooff T, Blocken B. CFD evaluation of natural ventilation of indoor environments by the concentration decay method: CO2 gas dispersion from a semi-enclosed stadium. Building and Environment, 2013; 61: 1–17.

Lee S-Y, Lee I-B, Kim R-W. Evaluation of wind-driven natural ventilation of single-span greenhouses built on reclaimed coastal land. Biosystems Engineering, 2018; 171: 120–142.

Montazeri H, Montazeri F. CFD simulation of cross-ventilation in buildings using rooftop wind-catchers: Impact of outlet openings. Renewable Energy, 2018; 118: 502–520.