Review
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Year 2022, Volume: 3 Issue: 2, 397 - 429, 31.12.2022
https://doi.org/10.46592/turkager.1060019

Abstract

References

  • Abubakar S, Umaru S, Kaisan MU, Umar UA, Ashok B and Nanthagopal K (2018). Development and performance comparison of mixed-mode solar crop dryers with and without thermal storage. Renewable Energy, 128: 285-298.
  • Adepoju LA and Osunde ZD (2017). Effect of pretreatments and drying methods on some quantities of dried mango (Mangifera indica) fruit. Agricultural Engineering International: CIGR Journal, 19: 187-194.
  • Adeuwa TO, Ogunlowo AS and Ojo ST (2014). Development of hot air supplemented solar dryer for white yam (Dioscorea rotundata) slices. Journal of Agriculture and Veterinary Science, 7: 114-123.
  • Ajadi DA, Fajinmi GR and Sanusi YK (2007). Effect of dust on the performance of a locally designed solar dryer. Research Journal of Applied Sciences, 2: 251-254.
  • Ajao KR and Adedeji AA (2008). Assessing the drying rates of some crops in solar dryer (case study: vegetables, tubers and grain crops). USEP: Journal of Research Info. Civil Engineering, 5: 1-12.
  • Akinola AO and Fapetu OP (2006). Exergetic analysis of a mixed-mode solar dryer. Journal of Engineering and Applied Sciences, 1: 205-210.
  • Aliyu AB and Jibril H (2009). Utilization of greenhouse effect for solar drying of cassava chips. International Journal of Physical Sciences, 4: 615-622.
  • Aliyu B, Kabri HU and Pembe PD (2013). Performance evaluation of a village level solar dryer for tomato under Savanna climate: Yola, Northeastern Nigeria. Agric. Eng. Int. CIGR Journal, 15: 181-186.
  • Alonge AF and Hammed RO (2007). A direct passive solar dryer for tropical crops. African Crop Science Conference Proceedings, 18: 1643-1646.
  • Alonge AF and Adeboye OA (2012). Drying rates of some fruits and vegetables with passive solar dryers. International Journal of Agric. and Biological Engineering, 5: 83-90.
  • Anonymous, 2018. www.primiumtimes.com/news/top-news/264781-nigerias-population-now
  • Anonymous, 2019. www.cia.gov/library/publications/the-world-factbook/geos
  • Anonymous, 2022. Agriculture in Nigeria. https://en.wikipedia.org/wiki/Agriculture_in_Nigeria#:~:text=Major%20crops%20include%20beans%2C%20rice,groundnut%20and%20palm%20kernel%20oil.
  • Anyanwu CN, Oparaku OU, Onyegegbu SO, Egwuatu U, Edem NI, Egbuka K, Nwosu PN and Sharma VK (2012). Experimental investigation of a photovoltaic-powered solar cassava dryer. Drying Technology: An International Journal, 30: 398-403.
  • Babagana G, Silas K and Mustapha BG (2012). Design and construction of forced/natural convection solar vegetable dryer with heat storage. ARPN Journal of Engineering and Applied Science, 7: 1213-1217.
  • Bala BK and Debnath N (2012). Solar drying technology: Potentials and developments. Journal of Fundamentals of Renewable Energy and Applications, 2: 1-5.
  • Bolaji BO (2005). Performance evaluation of a simple solar dryer for food preservation. The 6th Annual Engineering Conference Proceedings, FUT Minna, June.
  • Bolaji BO and Olalusi AP (2008). Performance evaluation of a mixed-mode solar dryer. AU Journal of Technology, 11(4): 225-231.
  • Bolaji OB, Olayanju MAT and Falade OT (2011). Performance evaluation of a solar wind-ventilated cabinet dryer. The West Indian Journal of Engineering, 33: 12-18.
  • Chauhan PS, Kumar A and Tekasakul P (2015). Application of software in solar drying systems: A review. Renewable and Sustainable Energy Review, 51: 1326-1337.
  • Dairo OU, Aderinlewo AA, Adeosun OJ, Ola IA and Salaudeen T (2015). Solar drying kinetics of cassava slices in a mixed mode flow dryer. Acta Technologies Agriculture, 4: 102 -107.
  • Eke BA (2013). Development of small-scale direct mode natural convection solar dryer for tomato, okra and carrot. International Journal of Engineering and Technology, 3: 199 - 204.
  • Eke BA (2014). Investigation of low-cost solar collector for drying vegetables in rural areas. Agric. Eng. Int. CIGR Journal, 16: 118-125.
  • Ekechukwu OV and Norton B (1995). Experimental studies of integral-type natural circulation solar energy tropical crop dryers. Energy Conversion and Management, 38: 1483-1500.
  • Ekechukwu OV and Norton B (1998). Effects of seasonal weather variations on the measured performance of a natural-circulation solar-energy tropical crop dryer. Energy Conversion and Management, 12: 1265-1276.
  • Ekechukwu OV and Norton B (1999a). Review of solar energy drying system III: low temperature air heating solar collectors for crop drying applications. Energy Conversion and Management, 20: 657-667.
  • Ekechukwu OV and Norton B (1999b). Review of solar-energy drying systems II: an overview of solar drying technology. Energy Conversion and Management, 40: 615-655.
  • Ekechukwu OV and Norton B (1999c). Review of solar energy drying systems I: An overview of drying principles and theory. Energy Conversion and Management, 40: 593-613.
  • Elhage H, Herez A, Ramadan M, Bazzi Hassan and Khaled M (2018). An investigation on solar drying: A review with economic and environmental assessment. Energy, 157: 815-829.
  • Enibe SO (2001). Performance of a natural circulation solar air heating system with phase change material energy storage. Renewable Energy, 27: 69-86.
  • Etim PJ, Eke AB and Simonyan KJ (2020). Design and development of an active indirect solar dryer for cooking banana. Scientific African, 8, e00463.
  • Eze JI and Agbo KE (2011). Comparative studies of sun and solar drying of peeled and unpeeled ginger. American Journal of Scientific and Industrial Researches, 2: 136-143.
  • Eze JI and Ojike O (2012). Studies on the effect of different solar dryers on the vitamin content of tomato (Solanum Lycoperscion). Journal of Renewable Energy, 4: 1-8.
  • Ezeanya NC, Akubuo CO, Chilakpu KO and Iheonye AC (2018). Modelling of thin layer solar drying kinetics of cassava noodles (Tapioca). Agric. Eng. Int. CIGR Journal, 20: 193-200.
  • Ezekoye BA and Enebe OM (2006). Development and performance evaluation of modified integrated passive solar dryer. The Pacific Journal of Science and Technology, 7: 185-190.
  • Fagunwa AO, Koya OA and Faborode MO (2009). Development of an intermittent solar dryer for coca beans. Agricultural Engineering Journal, 11: 1-4.
  • Finck-Pastrana AG (2014). Nopal (Opuntia lasiacantha) drying using an indirect solar dryer. Energy Procedia, 57: 2984-2993.
  • Fudholi A, Sopian K, Ruslan MH, Alghoul MA and Sulaiman MY (2010). Review of solar dryers for agricultural and marine products. Renewable and Sustainable Energy Reviews, 14: 1-30.
  • Hussein JB, Hassan MA, Kareem SA and Filli KB (2017). Design, construction and testing of a hybrid photovoltaic solar dryer. International Journal of Engineering Research and Science, 3: 1-14.
  • Ibrahim JS, Barki E and Edeoja AO (2015). Drying of chilli pepper using a solar dryer with a back-up incinerator under Markudi, humid climate. American Journal of Engineering Research, 4: 108-113.
  • Igbeka JC (1986). Evaluation of three types of solar dryers for Nigeria crops. Proceedings of a Workshop on Solar Drying in Africa held in Dakar, Senegal, pp. 162-174.
  • Ikrang EG, Onwe DN and Onda DO (2015). Development of a direct passive solar dryer for crayfish (Procambarus clarkii). International Journal of Engineering Research, Science and Technology, 4: 153-164.
  • Irtwange SV and Adebayo S (2009). Development and performance of a laboratory-scale passive solar grain dryer in a tropical environment. Journal of Agricultural Extension and Rural Development, 1: 42-49.
  • Isiaka M, El-Okene AMI and Muhammed US (2012). Effect of selected factors on drying process of tomato in forced convection solar energy dryer. Research Journal of Applied Sciences, Engineering and Technology, 4: 3637-3640.
  • Itodo IN, Ijabo JO, Charles JA, Ezeanaka NN and Akpa SO (2019). Performance of desiccant solar crop dryers in makurdi, Nigeria. American Society of Agricultural and Biological Engineers, 35: 259-270.
  • Iwe MO, Okoro C, Eke AB and Agiriga AN (2018). Mathematical modelling of thin layer solar drying of Ighu. Agricultural Engineering International CIGR Journal, 20: 149-156.
  • Kapadiya S and Desai MA (2014). Solar drying of natural and food products: A review. International Journal of Agriculture and Food Science Technology, 5: 565-576.
  • Kilanko O, Ilori TA, Leramo RO, Babalola PO, Eluwa SE, Onyenma FA, Ameh NI, Onwordi PN, Aworinde AK and Fajobi MA (2019). Design and performance evaluation of a solar dryer. IOP Publishing, Journal of Physics: Conference Series, 1378, 032001.
  • Kolawole FL, Balogun MA, Akeem SA and Salaudeen LA (2018). Effect of a drying methods on the yield, phytochemical compositon and antioxidant activities of potato (Solanum tuberosum) and two sweet potato (Ipomoea Batatas) varieties. Carpathian Journal of Food Science and Technology, 10: 107-119.
  • Komolafe CA and Waheed MA (2018). Design and fabrication of a forced convection solar dryer integrated with heat storage materials. Annales de Chimie - Science des Materiaux, 1: 23-39.
  • Komolafe CA, Ojediran JO, Ajao FO, Dada OA, Afolabi YT, Oluwaleye IO and Alake AS (2019). Modelling of moisture diffusivity during solar drying of locust beans with thermal storage material under forced and natural convection mode. Case Studies in Thermal Engineering, 15, 100542.
  • Komolafe CA, Waheed MA, Kuye SI, Adewumi BA, Oluwaleye IO and Olayanju TMA (2020). Sun drying of cocoa with firebrick thermal storage materials. International Journal of Energy Research, 44: 7015-7025.
  • Komolafe CA, Waheed MA, Kuye SI, Adewumi BA and Adejumo AOD (2021). Thermodynamic analysis of forced convective solar drying of cocoa with black coated sensible thermal storage material. Case Studies in Thermal Engineering, 26, 101140.
  • Kouchakzadeh A (2016). The hybrid drying of pistachios by solar energy and high electric field. Agricultural Engineering International CIGR Journal, 18: 129-137.
  • Kuhe A, Ibrahim JS, Tuleun LT and Akanji SA (2022) Effect of air mass flow rate on the performance of a mixed-mode active solar crop dryer with a transpired air heater. International Journal of Ambient Energy, 43: 531-538.
  • Kumari A, Singh R, Prakash O and Shutosh A (2014). Review on global solar drying status. Agricultural Engineering International CIGR Journal, 16: 161-177.
  • Lawrence D, Folayan CO and Pam GY (2013). Design, construction and performance evaluation of a mixed-mode solar dryer. International Journal of Engineering and Science (IJES), 1: 8-16.
  • Leon MA, Kumar S and Bhattacharya SC (2002). A comprehensive procedure for the performance evaluation of solar dryers. Renewable and Sustainable Energy Reviews, 6: 367-393.
  • Lopez-Vidana EC, Mendez-Lagunas LL and Rodriguez-Ramirez J (2013). Efficiency of a hybrid solar-gas dryer. Solar Energy Journal, 93: 23-31.
  • Mulet A, Berna A, Rosello C and Canellas J (1993). Analysis of open sun drying experiments. Drying Technology Journal, 2: 1385-1400.
  • Musa NA (2012). Drying characteristics of Cocoa beans using an artificial dryer. Journal of Engineering and Applied Sciences, 7: 194-197.
  • Mustapha MK, Ajibola TB, Ademola SK and Salako AF (2014). Proximate analysis of fish dried with solar dryers. Ital. Journal of Food Science, 26: 221-226.
  • Ndukwu MC, Onyenwigwe D, Abam FI, Eke AB and Dirioha C (2020a). Development of a low-cost wind-powered active solar dryer integrated with glycerol as thermal storage. Renewable Energy, 154, 553-568.
  • Ndukwu MC, Diemuodeke EO, Abam FI, Abada UC, Eke N, Tagne MS (2020b). Development and modelling of heat and mass transfer analysis of a low-cost solar dryer integrated with biomass heater: Application for West African Region. Scientific African, 10, e00615.
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Review on Solar Drying in Nigeria

Year 2022, Volume: 3 Issue: 2, 397 - 429, 31.12.2022
https://doi.org/10.46592/turkager.1060019

Abstract

Nigeria, as one of the countries in the African continent has its challenges regarding to agricultural crops cultivation and its preservation methods. Traditional methods of preserving crops are commonly adopted by the local populace over solar dryer appliances. The reason for these includes being cheaper method, does not require much technical know-how, is easily learnable, the area for drying the agricultural crop produce being unlimited etc as when compared to solar dryers that needs materials to be fabricated, required little or medium knowledge of technical know-how, financial requirement for its fabrication which could range from few dollars to thousands of dollars. Solar dryer working principles, components, various classifications, and its mode of air movement and mode of heat transfer were discussed on this article. The article also reviewed some of the experimental researches on solar drying in Nigeria carried out by various scholars. The review of the published works on solar drying of various crops under different drying techniques were carefully studied. The results showed that, significant works on solar drying in Nigeria have been carried out even though its potential is greatly under-utilized due to various factors militating against it.

References

  • Abubakar S, Umaru S, Kaisan MU, Umar UA, Ashok B and Nanthagopal K (2018). Development and performance comparison of mixed-mode solar crop dryers with and without thermal storage. Renewable Energy, 128: 285-298.
  • Adepoju LA and Osunde ZD (2017). Effect of pretreatments and drying methods on some quantities of dried mango (Mangifera indica) fruit. Agricultural Engineering International: CIGR Journal, 19: 187-194.
  • Adeuwa TO, Ogunlowo AS and Ojo ST (2014). Development of hot air supplemented solar dryer for white yam (Dioscorea rotundata) slices. Journal of Agriculture and Veterinary Science, 7: 114-123.
  • Ajadi DA, Fajinmi GR and Sanusi YK (2007). Effect of dust on the performance of a locally designed solar dryer. Research Journal of Applied Sciences, 2: 251-254.
  • Ajao KR and Adedeji AA (2008). Assessing the drying rates of some crops in solar dryer (case study: vegetables, tubers and grain crops). USEP: Journal of Research Info. Civil Engineering, 5: 1-12.
  • Akinola AO and Fapetu OP (2006). Exergetic analysis of a mixed-mode solar dryer. Journal of Engineering and Applied Sciences, 1: 205-210.
  • Aliyu AB and Jibril H (2009). Utilization of greenhouse effect for solar drying of cassava chips. International Journal of Physical Sciences, 4: 615-622.
  • Aliyu B, Kabri HU and Pembe PD (2013). Performance evaluation of a village level solar dryer for tomato under Savanna climate: Yola, Northeastern Nigeria. Agric. Eng. Int. CIGR Journal, 15: 181-186.
  • Alonge AF and Hammed RO (2007). A direct passive solar dryer for tropical crops. African Crop Science Conference Proceedings, 18: 1643-1646.
  • Alonge AF and Adeboye OA (2012). Drying rates of some fruits and vegetables with passive solar dryers. International Journal of Agric. and Biological Engineering, 5: 83-90.
  • Anonymous, 2018. www.primiumtimes.com/news/top-news/264781-nigerias-population-now
  • Anonymous, 2019. www.cia.gov/library/publications/the-world-factbook/geos
  • Anonymous, 2022. Agriculture in Nigeria. https://en.wikipedia.org/wiki/Agriculture_in_Nigeria#:~:text=Major%20crops%20include%20beans%2C%20rice,groundnut%20and%20palm%20kernel%20oil.
  • Anyanwu CN, Oparaku OU, Onyegegbu SO, Egwuatu U, Edem NI, Egbuka K, Nwosu PN and Sharma VK (2012). Experimental investigation of a photovoltaic-powered solar cassava dryer. Drying Technology: An International Journal, 30: 398-403.
  • Babagana G, Silas K and Mustapha BG (2012). Design and construction of forced/natural convection solar vegetable dryer with heat storage. ARPN Journal of Engineering and Applied Science, 7: 1213-1217.
  • Bala BK and Debnath N (2012). Solar drying technology: Potentials and developments. Journal of Fundamentals of Renewable Energy and Applications, 2: 1-5.
  • Bolaji BO (2005). Performance evaluation of a simple solar dryer for food preservation. The 6th Annual Engineering Conference Proceedings, FUT Minna, June.
  • Bolaji BO and Olalusi AP (2008). Performance evaluation of a mixed-mode solar dryer. AU Journal of Technology, 11(4): 225-231.
  • Bolaji OB, Olayanju MAT and Falade OT (2011). Performance evaluation of a solar wind-ventilated cabinet dryer. The West Indian Journal of Engineering, 33: 12-18.
  • Chauhan PS, Kumar A and Tekasakul P (2015). Application of software in solar drying systems: A review. Renewable and Sustainable Energy Review, 51: 1326-1337.
  • Dairo OU, Aderinlewo AA, Adeosun OJ, Ola IA and Salaudeen T (2015). Solar drying kinetics of cassava slices in a mixed mode flow dryer. Acta Technologies Agriculture, 4: 102 -107.
  • Eke BA (2013). Development of small-scale direct mode natural convection solar dryer for tomato, okra and carrot. International Journal of Engineering and Technology, 3: 199 - 204.
  • Eke BA (2014). Investigation of low-cost solar collector for drying vegetables in rural areas. Agric. Eng. Int. CIGR Journal, 16: 118-125.
  • Ekechukwu OV and Norton B (1995). Experimental studies of integral-type natural circulation solar energy tropical crop dryers. Energy Conversion and Management, 38: 1483-1500.
  • Ekechukwu OV and Norton B (1998). Effects of seasonal weather variations on the measured performance of a natural-circulation solar-energy tropical crop dryer. Energy Conversion and Management, 12: 1265-1276.
  • Ekechukwu OV and Norton B (1999a). Review of solar energy drying system III: low temperature air heating solar collectors for crop drying applications. Energy Conversion and Management, 20: 657-667.
  • Ekechukwu OV and Norton B (1999b). Review of solar-energy drying systems II: an overview of solar drying technology. Energy Conversion and Management, 40: 615-655.
  • Ekechukwu OV and Norton B (1999c). Review of solar energy drying systems I: An overview of drying principles and theory. Energy Conversion and Management, 40: 593-613.
  • Elhage H, Herez A, Ramadan M, Bazzi Hassan and Khaled M (2018). An investigation on solar drying: A review with economic and environmental assessment. Energy, 157: 815-829.
  • Enibe SO (2001). Performance of a natural circulation solar air heating system with phase change material energy storage. Renewable Energy, 27: 69-86.
  • Etim PJ, Eke AB and Simonyan KJ (2020). Design and development of an active indirect solar dryer for cooking banana. Scientific African, 8, e00463.
  • Eze JI and Agbo KE (2011). Comparative studies of sun and solar drying of peeled and unpeeled ginger. American Journal of Scientific and Industrial Researches, 2: 136-143.
  • Eze JI and Ojike O (2012). Studies on the effect of different solar dryers on the vitamin content of tomato (Solanum Lycoperscion). Journal of Renewable Energy, 4: 1-8.
  • Ezeanya NC, Akubuo CO, Chilakpu KO and Iheonye AC (2018). Modelling of thin layer solar drying kinetics of cassava noodles (Tapioca). Agric. Eng. Int. CIGR Journal, 20: 193-200.
  • Ezekoye BA and Enebe OM (2006). Development and performance evaluation of modified integrated passive solar dryer. The Pacific Journal of Science and Technology, 7: 185-190.
  • Fagunwa AO, Koya OA and Faborode MO (2009). Development of an intermittent solar dryer for coca beans. Agricultural Engineering Journal, 11: 1-4.
  • Finck-Pastrana AG (2014). Nopal (Opuntia lasiacantha) drying using an indirect solar dryer. Energy Procedia, 57: 2984-2993.
  • Fudholi A, Sopian K, Ruslan MH, Alghoul MA and Sulaiman MY (2010). Review of solar dryers for agricultural and marine products. Renewable and Sustainable Energy Reviews, 14: 1-30.
  • Hussein JB, Hassan MA, Kareem SA and Filli KB (2017). Design, construction and testing of a hybrid photovoltaic solar dryer. International Journal of Engineering Research and Science, 3: 1-14.
  • Ibrahim JS, Barki E and Edeoja AO (2015). Drying of chilli pepper using a solar dryer with a back-up incinerator under Markudi, humid climate. American Journal of Engineering Research, 4: 108-113.
  • Igbeka JC (1986). Evaluation of three types of solar dryers for Nigeria crops. Proceedings of a Workshop on Solar Drying in Africa held in Dakar, Senegal, pp. 162-174.
  • Ikrang EG, Onwe DN and Onda DO (2015). Development of a direct passive solar dryer for crayfish (Procambarus clarkii). International Journal of Engineering Research, Science and Technology, 4: 153-164.
  • Irtwange SV and Adebayo S (2009). Development and performance of a laboratory-scale passive solar grain dryer in a tropical environment. Journal of Agricultural Extension and Rural Development, 1: 42-49.
  • Isiaka M, El-Okene AMI and Muhammed US (2012). Effect of selected factors on drying process of tomato in forced convection solar energy dryer. Research Journal of Applied Sciences, Engineering and Technology, 4: 3637-3640.
  • Itodo IN, Ijabo JO, Charles JA, Ezeanaka NN and Akpa SO (2019). Performance of desiccant solar crop dryers in makurdi, Nigeria. American Society of Agricultural and Biological Engineers, 35: 259-270.
  • Iwe MO, Okoro C, Eke AB and Agiriga AN (2018). Mathematical modelling of thin layer solar drying of Ighu. Agricultural Engineering International CIGR Journal, 20: 149-156.
  • Kapadiya S and Desai MA (2014). Solar drying of natural and food products: A review. International Journal of Agriculture and Food Science Technology, 5: 565-576.
  • Kilanko O, Ilori TA, Leramo RO, Babalola PO, Eluwa SE, Onyenma FA, Ameh NI, Onwordi PN, Aworinde AK and Fajobi MA (2019). Design and performance evaluation of a solar dryer. IOP Publishing, Journal of Physics: Conference Series, 1378, 032001.
  • Kolawole FL, Balogun MA, Akeem SA and Salaudeen LA (2018). Effect of a drying methods on the yield, phytochemical compositon and antioxidant activities of potato (Solanum tuberosum) and two sweet potato (Ipomoea Batatas) varieties. Carpathian Journal of Food Science and Technology, 10: 107-119.
  • Komolafe CA and Waheed MA (2018). Design and fabrication of a forced convection solar dryer integrated with heat storage materials. Annales de Chimie - Science des Materiaux, 1: 23-39.
  • Komolafe CA, Ojediran JO, Ajao FO, Dada OA, Afolabi YT, Oluwaleye IO and Alake AS (2019). Modelling of moisture diffusivity during solar drying of locust beans with thermal storage material under forced and natural convection mode. Case Studies in Thermal Engineering, 15, 100542.
  • Komolafe CA, Waheed MA, Kuye SI, Adewumi BA, Oluwaleye IO and Olayanju TMA (2020). Sun drying of cocoa with firebrick thermal storage materials. International Journal of Energy Research, 44: 7015-7025.
  • Komolafe CA, Waheed MA, Kuye SI, Adewumi BA and Adejumo AOD (2021). Thermodynamic analysis of forced convective solar drying of cocoa with black coated sensible thermal storage material. Case Studies in Thermal Engineering, 26, 101140.
  • Kouchakzadeh A (2016). The hybrid drying of pistachios by solar energy and high electric field. Agricultural Engineering International CIGR Journal, 18: 129-137.
  • Kuhe A, Ibrahim JS, Tuleun LT and Akanji SA (2022) Effect of air mass flow rate on the performance of a mixed-mode active solar crop dryer with a transpired air heater. International Journal of Ambient Energy, 43: 531-538.
  • Kumari A, Singh R, Prakash O and Shutosh A (2014). Review on global solar drying status. Agricultural Engineering International CIGR Journal, 16: 161-177.
  • Lawrence D, Folayan CO and Pam GY (2013). Design, construction and performance evaluation of a mixed-mode solar dryer. International Journal of Engineering and Science (IJES), 1: 8-16.
  • Leon MA, Kumar S and Bhattacharya SC (2002). A comprehensive procedure for the performance evaluation of solar dryers. Renewable and Sustainable Energy Reviews, 6: 367-393.
  • Lopez-Vidana EC, Mendez-Lagunas LL and Rodriguez-Ramirez J (2013). Efficiency of a hybrid solar-gas dryer. Solar Energy Journal, 93: 23-31.
  • Mulet A, Berna A, Rosello C and Canellas J (1993). Analysis of open sun drying experiments. Drying Technology Journal, 2: 1385-1400.
  • Musa NA (2012). Drying characteristics of Cocoa beans using an artificial dryer. Journal of Engineering and Applied Sciences, 7: 194-197.
  • Mustapha MK, Ajibola TB, Ademola SK and Salako AF (2014). Proximate analysis of fish dried with solar dryers. Ital. Journal of Food Science, 26: 221-226.
  • Ndukwu MC, Onyenwigwe D, Abam FI, Eke AB and Dirioha C (2020a). Development of a low-cost wind-powered active solar dryer integrated with glycerol as thermal storage. Renewable Energy, 154, 553-568.
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There are 88 citations in total.

Details

Primary Language English
Subjects Agricultural Engineering
Journal Section Review
Authors

Henry Okonkwo 0000-0002-0693-3982

Can Ertekin 0000-0003-2987-2438

Early Pub Date December 16, 2022
Publication Date December 31, 2022
Submission Date April 12, 2022
Acceptance Date June 28, 2022
Published in Issue Year 2022 Volume: 3 Issue: 2

Cite

APA Okonkwo, H., & Ertekin, C. (2022). Review on Solar Drying in Nigeria. Turkish Journal of Agricultural Engineering Research, 3(2), 397-429. https://doi.org/10.46592/turkager.1060019

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