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Numerical simulation and experimental validation study of a mixed-mode solar dryer for cocoa beans
Performance of a mixed-mode solar dryer prototype for cocoa beans was optimized by geometrical optimization of the dryer using numerical simulation. A mixed mode solar dryer was modelled, numerically simulated using computational fluid dynamic (CFD), and the thermal performance of the modelled dryer was experimentally validated for a 50 kg thin layer mass configuration of cocoa beans under no load condition. The simulation parameters include drying chamber cross-sectional area, drying chamber height, drying tray (plenum) position, collector inclination angle as well as velocity of air flow. The simulated results were obtained with reasonable accuracy, and this result showed good agreement with experimental results. In addition, the dryer temperature from experimental validation was higher than that from a similar dryer evaluated by a previous research group from our laboratory. The simulation results show that the dryer performance is optimal at 1 m2 drying chamber cross-sectional area, 0.2 m drying chamber height and drying tray position placed at a depth 0.1 m from the bottom of the plenum chamber. Also, optimal collector inclination of 14° was obtained. This narrow the analytical-based wide range of collector inclination angle recommended in literatures to (α - 6.5) ≤ β ≥ (α + 6.5) of the earth polar system.
Numerical simulation and experimental validation study of a mixed-mode solar dryer for cocoa beans
Performance of a mixed-mode solar dryer prototype for cocoa beans was optimized by geometrical optimization of the dryer using numerical simulation. A mixed mode solar dryer was modelled, numerically simulated using computational fluid dynamic (CFD), and the thermal performance of the modelled dryer was experimentally validated for a 50 kg thin layer mass configuration of cocoa beans under no load condition. The simulation parameters include drying chamber cross-sectional area, drying chamber height, drying tray (plenum) position, collector inclination angle as well as velocity of air flow. The simulated results were obtained with reasonable accuracy, and this result showed good agreement with experimental results. In addition, the dryer temperature from experimental validation was higher than that from a similar dryer evaluated by a previous research group from our laboratory. The simulation results show that the dryer performance is optimal at 1 m2 drying chamber cross-sectional area, 0.2 m drying chamber height and drying tray position placed at a depth 0.1 m from the bottom of the plenum chamber. Also, optimal collector inclination of 14° was obtained. This narrow the analytical-based wide range of collector inclination angle recommended in literatures to (α - 6.5) ≤ β ≥ (α + 6.5) of the earth polar system.
Numerical simulation and experimental validation study of a mixed-mode solar dryer for cocoa beans
Samuel Ayobami Adeyemi (author) / Surajudeen Olarewaju Obayopo (author) / Felix Akharume (author)
2019-06-29
oai:zenodo.org:3698248
Journal of Postharvest Technology 07(3) 96-114
Article (Journal)
Electronic Resource
English
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