Mejora de la eficiencia de la generación fotovoltaica adaptándose a los elementos meteorológicos
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La producción de electricidad limpia que no dañe los sistemas medioambientales ha sido una de las principales carreras mundiales de los últimos tiempos. Los niveles de radiación ultravioleta, enviada a través de la luz solar, que pueden ser captadas por células fotovoltaicas y transformar la luz en energía eléctrica, hacen del sol la fuente más prometedora para satisfacer las necesidades eléctricas de los seres humanos. El clima tiene una importancia considerable a la hora de captar energía solar, ya que la eficiencia de un sistema celular está directamente relacionada con las condiciones climáticas locales. Este trabajo tiene como objetivo analizar la influencia de los elementos meteorológicos en la eficiencia de la generación de energía fotovoltaica y su efecto climático. La metodología se basa en la medición de la generación de electricidad mediante celdas fotovoltaicas, en la recopilación de elementos meteorológicos y temperatura del panel; en el estudio de la relación entre la generación de electricidad mediante células fotovoltaicas y el resto de parámetros y en el estudio de los parámetros para la mejora de la eficiencia de la generación de energía limpia.
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AMARAL, TR, NAVEIRA-COTTA, CP, NASSER, LS, BEZERRA, BS, SANTOS, AM, & LIMA, RP (2019). Environmental performance of hydropower plants: A Brazilian case study. Journal of Cleaner Production, 232 , 751-763.
ANEEL. (2008). Atlas of Electrical Energy. National Electric Energy Agency, Brasilia.
ANEEL. (2018). Performance Report for Centrally Dispatched Thermoelectric Power Plants – Types IE Iiad. National Electric Energy Agency, Brasilia.
ANEEL. (2022). Generation Information Bank. National Electric Energy Agency, Brasilia.
ARMSTRONG, S., & HURLEY, W. (2010). A thermal model for photovoltaic panels under varying atmospheric conditions. Appl Therm Eng, 30 , 11-12.
BARROS, N.E. (2021). Greenhouse gas emissions from hydroelectric reservoirs: what knowledge do we have and what needs to be done? Renewable and Sustainable Energy Reviews, 147 , 111-131.
BUDAY, M. (2011). Measuring irradiance, temperature Corkishe and angle of incidence effects on photovoltaic modules in Auburn Hills. Michigan: University of Michigan.
CHOKMAVIROJ, S., WATTANAPONG, R., & SUCHART, Y. (2006). Performance of a 500 kWp Grid Connected Photovoltaic System at Mae Hong Son Province, Thailand. Renewable Energy, 31 , 19.
DIAF, S., NOTTON, G., BELHAMEL, M., HADDADI, M., & LOUCHE, A. (2008). Design and technoeconomical optimization for hybrid PV/wind system under various meteorological conditions. Applied Energy, 85 , 968-987.
FEARNSIDE, PM (2020). Large hydroelectric dams in Brazilian Amazonia: A flawed climate solution?. Environmental Science & Policy, 112, 215-225.
JACQUES, S; CALDEIRA, A; REN, Z; SCHELLMANNS, A; BATUT, N. Impact of the cell temperature on the energy efficiency of a single glass PV module: thermal modeling in steady-state and validation by experimental data. In: Proceedings of the international conference on renewable energies and power quality 2013 (ICREPQ'13) Bilbao, Spain.
HAMROUNI, N., JRAIDI, M., & CHÉRIF, A. (1995). Solar radiation and ambient temperature effects on the performances of a PV pumping system. Revue des Energies Renouvelables , pp. 95 – 106.
HANIFI, HP (2018). A Practical Optical and Electrical Model to Estimate the Power Losses and Quantification of Different Heat Sources in Silicon Based PV Module. Renewable Energy , pp. 602-612.
KHOLOD, Yana et al. Excitation Energy Transfer Pathways in Light ‐ harvesting Proteins: Modeling with PyFREC. Journal of Computational Chemistry, v. 39, no. 8, p. 438-449, 2018. Available at: https://onlinelibrary.wiley.com/doi/abs/10.1002/jcc.25101. Epub.
LOUIS, VL ST.; KELLY, CLA; DUCHEMIN, É.; RUDD, JWM; ROSENBERG, DM Reservoir surfaces as sources of greenhouse gases to the atmosphere: a global estimate. BioScience, v. 50, no. 9, p. 766-775, 2000.
HAYAT, MB, Ali, D., MONYAKE, KC, ALAGHA, L., & AHMED, N. (2019). Solar Energy-A Look into Power Generation, Challenges, and A Solar-Powered Future. J. Energy Res. , pp. 1049–1067.
IPCC. (2021). Climate Change 2021: The Physical Science Basis. Contribution of Working Group I to the Sixth Assessment Report of the Intergovernmental Panel on Climate Change. Cambridge: Intergovernmental Panel on Climate Change.
JAIN, Sachin, DHARA, Sumon, AGARWAL, Vivek. A Voltage-Zone Based Power Management Scheme With Seamless Power Transfer Between PV-Battery for OFF-Grid Stand-Alone System. IEEE Transactions on Industry Applications, v. 57, no. 1, p. 754-763, 2021. Available at: https://ieeexplore.ieee.org/document/9319219. Epub.
KALDELLIS, JK, KAVADIAS K., ZAFIRAKIS D. Experimental validation of the optimum photovoltaic panels' tilt angle for remote consumers. Renew Energy 2012; 46: 179 and 91.
KALDELLIS, JK; KAPSALI, M.; KAVADIAS, KA Temperature and wind speed impact on the efficiency of PV installations. experience obtained from outdoor measurements in greece, Renewable Energy 66 (2014) 612–624.
LV, JWX; ZHU, H.;, SONG, Y. The influence of meteorological factors on the photovoltaic daily generation (2014). doi:10.13941/j.cnki.21-1469/tk.2014.10.001.
MATIN, MA et al. Bi(1-y)SmyFeO3 as potential photovoltaic materials. Bull Mater Sci, v. 43, p. 167, 2020. https://doi-org.ez130.
MIRANDA, MM (2012). Emission factor of greenhouse gases from electricity generation in Brazil: implications of applying the Life Cycle Assessment. 162p. Dissertation (Master). Engineering School of São Carlos. University of São Paulo. 2012.
MME - Ministry of Mines and Energy. National Energy Plan 2050. (2018). https://www.mme.gov.br/documents/10584/1102077/PNE+2050+-+vers%C3%A3o+final.pdf/3e3d0dbb-bf14-0c48-c287-0d4f3e33df44.
NAVNTOFT, LC, CRISTÓFALO, MP, CUCCORESE, S., DEFFERRARI, IR, & ROMERO, I. (2019). Manual de Generación Distribuida Solar Fotovoltaica (1st revised ed.). Secretariat of the Government of Energy.
NEVES, A; BLONDEL, L; BRAND, K; HENDEL, B.S; RIVAS, CS; IANCU, A; MELICA, G; KOFFI, L.B; ZANCANELLA, P; KONA, A. Guide for presenting the results of the Covenant of Mayors for Climate and Energy, 2016, EUR 28160 PT, doi: 10.2790/717311.
PUEYO, S.; FEARNSIDE, PM GREENHOUSE GAS EMISSIONS FROM HYDROELECTRIC RESERVOIRS: IMPLICATIONS OF A POWER LAW. Oecologia Australis 15(2): 199-212, June 2011 doi:10.4257/oeco.2011.1502.02.
RAZA. A, Syed J, Muhammad Ali F, et al. Incidence of Vitamin D Deficiency in Different Seasons in the Adult Karachi Population Presenting in the Medical Outpatient Department with Generalized Body Ache. Cureus, v. 11, no. 7, p. e5167, 2019. DOI: 10.7759/cureus.5167.
SANCHES, SR Meteorological Data Transmission System in Real Time for Marina Users' Cell Phones. Florianopolis: IFSC, 2020.
SANTOS, MA; ROSA, LP; MATVIENKO, B.; SANTOS, EO; D'ALMEIDA ROCHA, CHE; SIKAR, E.; SILVA, MB & JUNIOR, AMPB 2008. Greenhouse gas emissions from hydroelectric reservoirs. Oecologia Brasiliensis, 12: 116-129.
SOARES FILHO et al. Low Carbon Study for Brazil - Land Use, Land Use Change and Forests, 2010. International Bank for Reconstruction and Development.
WOLFE, Philip R. "What Is Photovoltaics?" In: The Solar Generation. 1st ed. Hoboken, NJ, USA: Wiley, 2018. p. 9-24.
ZANONI, Maria MV, Josiléia A. Zanatta, Jeferson Dieckow, Akemi Kan, and Carlos B. Reissmann. "Methane Emissions from Decomposition of Flooded Forestry Waste." Brazilian Journal of Agricultural and Environmental Engineering 19.2 (2015): 173-79.