Projeto de sistema solar térmico autônomo para desidratação indireta de Aguaymanto (Physalis Peruviana L.), Junín
Barra lateral de artigos
Publicado:
2021-02-25
Palavras-chave:
Agroindustrial, desidratação, coletor solar, sistema solar térmico, aguaymanto
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Resumo
Com o propósito de ter um secador solar indireto autônomo para desidratar aguaymanto (uchuva), da region alta central em nosso país, foi proposto um protótipo de secador solar autônomo de 100 kg por lote de aguaymanto, com refletores planos e ar forçado usando energia fotovoltaica que permite uma secagem da fruta com qualidade de acordo aos requisitos de exportação. As dimensões do secador são as seguintes: dimensões internas da câmara de secagem com profundidade de 0,60 m, largura 1,40 m altura 1,10 m e 0,05 m de isolamento, as medidas externas são, profundidade de 0,70 m, largura de 1,50 m, altura de 1,20 m . São propostos dois coletores solares com dimensões de: 1,50 m de largura, 2,40 m de comprimento e 0,15 m de altura, serão necessários 2 espelhos refletores planos. Um painel fotovoltaico de 80 Wp foi selecionado para o sistema de ar forçado e controle de processo. Este secador solar permitirá resolver o problema de deteriodo pós-colheita e facilitará a exportação com qualidade e menor custo econômico.
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Universidad Politécnica Salesiana of Ecuador preserves the copyrights of the published works and will favor the reuse of the works. The works are published in the electronic edition of the journal under a Creative Commons Attribution/Noncommercial-No Derivative Works 3.0 Ecuador license: works can be copied, used, disseminated, transmitted and publicly displayed.
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Sándor, Zs., Tállai, M., Kincses, I., László, Z., Kátai, J., and Vágó, I. (2020). Effect of various soil cultivation methods on some microbial soil properties. DRC Sustainable Future, 1(1):14-20. DOI: 10.37281/DRCSF/1.1.3
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Marcucci, A., and Turton. H. (2015). Induced technological change in moderate and fragmented climate change mitigation regimes. Technol Forecast Soc Change, 90:230-242.
Lachuriya, A., and Kulkarni, R.D. (2017). Stationary electrical energy storage technology for global energy sustainability: A review,” 2017 International Conference on Nascent Technologies in Engineering (ICNTE), Navi Mumbai, India, Jan. 27-28, 2017, pp.1-6.
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Bhandari, R, Stadler, I. (2009). Grid parity analysis of solar photovoltaic systems in Germany using experience curves. Solar Energy, 83(9):1634–44.
Luigi, D, and Enrico, T. (2010). Economic analysis of different supporting policies for the production of electrical energy by solar photovoltaics in western European Union countries. Energy Policy, 38(7):3297–308.
Campoccia, A., Dusonchet, L., Telaretti, E., and Zizzo, G. (2009). Comparative analysis of different supporting measures for the production of electrical energy by solar PV and Wind systems: four representative European cases. Solar Energy, 83(3):287–97.
Dusonchet, L., and Telaretti, E. (2010). Economicanalysisofdifferentsupportingpoliciesfor the production of electrical energy by solar photovoltaics in western Euro- pean Union countries. Energy Policy, 38(7): 3297–308.
Wang, Q., and Qiu, H.N. (2009). Situation and outlook of solar energy utilization in Tibet,China. Renewable Sustainable Energy Rev, 13(8):2181–6.
Calde?s, N., Varela, M., Santamari?a, M, Sa?ez, R. (2009). Economic impact of solar thermal electricity deployment in Spain. Energy Policy, 37(5):1628–36.
Wang, Q. (2010). Effective policies for renewable energy – the example of China’s wind power – lessons for China’s photovoltaic power. Renewable Sustainable Energy Rev, 14(2):702–12.
Ashraf, CM, Raza, R., Hayat, S.A. (2009). Renewable energy technologies in Pakistan: prospects and challenges. Renewable Sustainable Energy Rev, 13(6–7):1657–1662.
Espinoza, R. (1991). Teoría y práctica del secado solar - Google Libros (UNI, Ed.). Retrieved from https://books.google.com.pe/books/about/Teoría_y_práctica_del_secado_solar.html?id=7vKGrgEACAAJ&redir_esc=y
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Gamio, P. (2014). Renewable Energies and Climate Change, 7 demonstrating projects sustainable development. In Konrad Adenauer Stiftung e.V.
Mekhilef, S., Saidur, R. & Safari, A. (2011). A review on solar energy use in industries. Renewable and Sustainable Energy Reviews, 15(4):1777–1790. https://doi.org/10.1016/J.RSER.2010.12.018
Timilsina, G. R., Kurdgelashvili, L. and Narbel, P. A. (2011). Solar energy: Markets, economics and policies. Renewable and Sustainable Energy Reviews, 16, 449–465. https://doi.org/10.1016/j.rser.2011.08.009
Roche-Delgado, L., Hernández-Touset, J. P. and García-Rodríguez, A. (2017). CONCEPTUAL DESIGN OF A PILOT SCALE SOLAR DRYER FOR MARINE ALGAE. Chemical Technology,37(2):184-200.Retrieved from http://scielo.sld.cu/scielo.php?script=sci_arttextid=S2224-61852017000200003
Benavides, L. (Exporting Sierra) (2014). PROJECT: INDUSTRIAL INNOVATION DEHYDRATATION OF BERRIES - AGUAYMANTO 2014-2015 | PDF Flipbook. Retrieved March 6, 2018, from Sierra Exportadora website: http://www.youblisher.com/p/1108803-PROYECTO-INNOVACION-INDUSTRIAL-DESHIDRATACION-DE-BERRIES-AGUAYMANTO-2014-2015/
AOAC (2000). Official Methods of Analysis. Retrieved from http://sutlib2.sut.ac.th/sut_contents/H125800.pdf
Camayo-Lapa, B. F., Pomachagua-Paucar, J. E., Massipe-Hernaández, J. R., Quispe-Flores, M. O. and Torres-Ten, A. (2017). Validation and application of the Bristow Campbell model to estimate the global solar radiation of the Junin region. Chemical Technology, 37(3): 574-590. Retrieved from http://scielo.sld.cu/scielo.php?script=sci_arttextid=S2224-61852017000300015