Food losses in the developing country are thought to be 50% of the fruits and
vegetables grown and 25% of harvested food grain. Food preservation can reduce
wastage of a harvest surplus, allow storage for food shortages, and in some
cases facilitate export to high-value markets. Drying is one of the oldest methods
of food preservation. Drying makes produce lighter, smaller, and less likely to
spoil and helps to minimize the moisture content in coffee beans as high
moisture content during storage is certain to ruin the taste and appearance of
coffee. This work presents the results of an experimental study of forced
convection drying of coffee cherries in a modified Icaro solar dryer. The study
aims to validate the numerical models developed for further research. The
experimental tests envisaged also aim to determine the mass loss curves of the
product by fixing or calculating its initial mass (1 kg), its initial water
content (70%), the ambient temperature, the drying airflow (0.02 m3.s-1 to 0.09 m3.s-1) and the exchange coefficients. The
influence of these aerothermal parameters on the drying time of a most
commercialized coffee variety (Robusta) was studied. Finally, the results
revealed an increase in the efficiency of the heat transfer air and a reduction
in the water content of the coffee cherry from 70% to 9.87%, after 30.2 hours.
References
[1]
Bechis, S. and Barigazzi, F. (2013) Manuel de construction et utilisation du séchoir Icaro 1.5. 2nd Edition, Italia.
[2]
Pakouzou, B.M., Ouédraogo, P.W.G., de Dieu Bokoyo, B.V., Ousman, M., Mackpayen, O.A., Kaboré, B. and Kam, S. (2022) Experimentation of the Solar Dryer with Parabolic Trough: Drying of Okra. International Journal of Advanced Engineering Research and Science, 9, 34-41. https://doi.org/10.22161/ijaers.91.5
[3]
Mackpayen, A.O., Gbembongo, T., Bolinguipa, J.M., Marboua Bara, L., Malenguinza, S. and Napo, K. (2015) Modélisation du profil de température et de la cinétique de séchage du café dans un séchoir. 5ème Séminaire Maghrébin Sur Les Sciences, Les Technol., Université KASDI MERBAH de Ouargla (UKMO), Algérie. https://sites.google.com/site/sechagesmsts/
[4]
Chara-Dackou, V.S., Njomo, D., Babikir, M.H., Mbouombouo, I.N., Pofoura Gboulie, S.A. and Tchinda, R. (2022) Processing Sunshine Duration Measurements for the Assessment of Solar Radiation in Climatic Regions of the Central African Republic. The Journal of Solar Energy Engineering, 144, 031002-031017. https://doi.org/10.1115/1.4053483
[5]
Udomkun, P., Romuli, S., Schock, S., Mahayothee, B., Sartas, M., Wossen, T., Njukwe, E., Vanlauwe, B. and Müller, J. (2020) Review of Solar Dryers for Agricultural Products in Asia and Africa: An Innovation Landscape Approach. Journal of Environmental Management, 268, Article ID: 110730. https://doi.org/10.1016/j.jenvman.2020.110730
[6]
Srinivasan, G., Rabha, D.K. and Muthukumar, P. (2021) A Review on Solar Dryers Integrated with Thermal Energy Storage Units for Drying Agricultural and Food Products. Solar Energy, 229, 22-38. https://doi.org/10.1016/j.solener.2021.07.075
[7]
Kumar, S. (2023) Variations in Top Heat Loss Coefficient with Sky Temperature for a Flat Plate Collector. National Academy Science Letters, 46, 31-35. https://doi.org/10.1007/s40009-022-01184-w
[8]
Hort Agro Solution Agencies (2021) Development of Standard Solar Dryers for Quality Coffee Processing Trainers Manual. Fairtrade Africa, Nairobi.
[9]
Das, M. and Akpinar, E.K. (2020) Determination of Thermal and Drying Performances of the Solar Air Dryer with Solar Tracking System: Apple Drying Test. Case Studies in Thermal Engineering, 21, Article ID: 100731. https://doi.org/10.1016/j.csite.2020.100731
[10]
Dissa, A.O. (2007) Séchage Convectif de la mangue: L’influence des paramètres aérauliques et Intrinsèques, conception et modélisation fonctionnement d’un séchoir solaire indirect. Ph.D. Thesis, Université de Ouagadougou, Ouagadougou.
[11]
Lankouande, R., Ouattara, F., Palm, K. and Kam, S. (2020) Modélisation et Expérimentation du Séchage Solaire Indirect en Couches Minces de Tranches de Tomates de la Variété Mongal. European Journal of Scientific Research, 156, 22-32.
