Abstract
An uneven-span modified greenhouse dryer was constructed and tested in no-load conditions under natural convection mode under the weather conditions of Marrakech, Morocco, for two distinct days. Moreover, a CFD evaluation of the uneven-span greenhouse dryer was performed as tool to visualize the air temperature distribution inside the dryer. For validating the CFD model, the temperature variations along the hours of the day were compared to the experimental results. A good agreement is obtained between the computed and measured inside air temperature with a difference not exceeding 8.46°C, with a correlation coefficient ( r ) and root mean square percentage deviations ( e ) 0.94 and 8.17, respectively. Furthermore, the maximum inside air temperature was measured to be 56°C and 52°C while the minimum inside relative humidity was measured to be 17% and 12%, for day-1 and day-2, respectively. The benefice of using asphalt as a floor covering material was revealed as an efficient way to heat the inside air at low solar radiations. The performances of the dryer were evaluated by the percentage of net heat gain variation as a way to validate the effectiveness of the dryer. This latter is found to be equal to 46% and 48% for the two days, respectively.
Highlights
Solar energy has received significant attention as an efficient, promising, durable, cost-effective, and environmentally friendly source of energy
The experimental measurements were conducted in an uneven-span greenhouse dryer under no-load conditions at different days from October to December 2020 at the Faculty of Sciences Semlalia (Marrakech-Morocco)
In order to evaluate the simulated performance of the uneven-span greenhouse dryer, the simulated inside air temperatures during day-1 and day-2 were compared with the experimental data
Summary
Solar energy has received significant attention as an efficient, promising, durable, cost-effective, and environmentally friendly source of energy. Vivekanandan et al [9] only evaluated the air temperature distribution inside six different types of greenhouse dryers by the mean of ANSYS Fluent, whereas Chauhan and Kumar [8] conducted only an experimental study of the performances of a greenhouse dryer in no-load conditions under natural convection, and Prakash and Kumar [16] studied only the effects of heat loss and the instantaneous thermal loss efficiency factor on the performances of a modified greenhouse dryer. The computational fluid dynamic package (ANSYS Fluent software) was used to evaluate the performance of an uneven-span greenhouse dryer at no-load conditions under the meteorological conditions of Marrakech-Morocco This greenhouse dryer is intended to be used for drying agricultural products with high moisture content. The key features of the greenhouse dryer system in this study are the roof inclination angle 12° and the floor covering material in order to capture the maximum of solar radiation and enhance its reradiated fraction, by consequence increasing the air temperature within the greenhouse dryer
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