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Development and modelling of heat and mass transfer analysis of a low-cost solar dryer integrated with biomass heater: Application for West African Region

Macmanus Chinenye Ndukwu, Ogheneruona E. Diemuodeke, Fidelis I. Abam, U. C. Abada, Nnanna Eke-emezie, Merlin Simo‐Tagne

2020Scientific African41 citationsDOIOpen Access PDF

Abstract

The main objective of this study is to design and fabricate a low-cost hybrid solar drying system and present the drying kinetics, heat transfer coefficient and thin layer models for the dried product. For this purpose, two solar dryers one equipped with biomass heater and the other without biomass heater were constructed and tested. The results show that the developed solar dryers can save between 27.78% and 58.33% of drying time compared to open sun drying method at ambient temperature ranging between 30 and 40 °C and a humidity ranging from 55% to 70%. Under these operating conditions, the collector efficiency is 20.81–21.89%. The values for the heat transfer coefficient ranged from 0.64 to 10.5 W/m2 °C. Verma et al. model gave the best result for drying with biomass heater while logarithmic model was best for drying without biomass heater.

Topics & Concepts

Solar dryerBiomass (ecology)Environmental scienceMass transferRangingMaterials scienceHeat transfer coefficientRelative humidityHumidityHeat transferSolar energyThin layerProcess engineeringPulp and paper industryNuclear engineeringLayer (electronics)MeteorologyThermodynamicsComposite materialEngineeringAgronomyElectrical engineeringGeographyTelecommunicationsPhysicsBiologyFood Drying and ModelingHeat Transfer MechanismsGreenhouse Technology and Climate Control
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